Area Seminar

Biogeochemical controls on dissolved micronutrient (Ni, Cu, Zn, Cd) distributions in the Equatorial Pacific Ocean

Date

2026-01-06

Speaker

Dr. Naman Deep Singh

Venue

Ground Floor Lecture Hall

Abstract

The Equatorial Pacific Ocean (EPO) is among the most productive oceanic regions and is characterized by strong CO2 outgassing, playing a pivotal role in the global carbon cycle. Here, we present the distributions of micronutrients along the German GEOTRACES GP11 transect in the EPO during a developing El Niño. This study aims to assess the biogeochemical controls governing micronutrient distributions along the transect, which are critical for elucidating potential linkages between surface productivity and nutrient supply. Model estimates combined with observational constraints indicate that equatorial upwelling and strong zonal currents exert primary controls on micronutrient fluxes and biological uptake ratios. These findings have important implications for the bioavailability of micronutrients in the surface EPO under an increasing frequency of extreme El Niño and La Niña events, which modulate upwelling strength and Equatorial Undercurrent (EUC) intensity across the EPO. Overall, this study highlights the differential impacts of water mass mixing and vertical processes including, organic matter remineralization, particle scavenging, and benthic fluxes, on micronutrient distributions in the EPO and provides new insights into their inter-basin variability and biogeochemical cycling in the Pacific Ocean. About the speaker: Dr. Naman Deep Singh is a geochemist and completed his integrated BS-MS degree at the Indian Institute of Science Education and Research (IISER) between 2010 and 2015, followed by a Ph.D. at the Physical Research Laboratory from 2015 to 2020. He is currently working as a postdoctoral researcher at GEOMAR Helmholtz Centre for Ocean Research in Kiel, Germany. His research interests focus on understanding the biogeochemical cycling of trace metals in the ocean and their influence on biological ocean productivity and chemical weathering processes in terrestrial systems.

Understanding Dwarf Novae Type Cataclysmic Variables

Date

2025-12-31

Speaker

Ayush Rana

Venue

113/114, Thaltej Campus

Abstract

Cataclysmic Variables (CVs) are close interacting binary systems consisting of a white dwarf accreting material from a late-type main-sequence companion via Roche-lobe overflow. Due to their small orbital separations, typically a few solar radii, CVs exhibit short orbital periods of a few hours and display strong photometric variability. Dwarf novae are a prominent subclass of CVs and are characterised by recurrent optical outbursts with amplitudes of 2–6 magnitudes and recurrence timescales ranging from weeks to months. These outbursts are understood with the disk instability model (DIM), in which thermal–viscous instabilities in the accretion disk drive transitions between quiescent and outburst states. Dwarf novae provide an excellent laboratory for studying accretion disk physics and time-dependent disk evolution. In eclipsing systems, changes in the disk structure can be probed using eclipse depth and out-of-eclipse flux measurements. Recent high-cadence photometric studies have revealed hysteresis behaviour in eclipse fraction diagrams, indicating a temporal lag between variations in mass accretion rate and disk radius during outburst cycles. In this talk, I present an overview of cataclysmic variables with emphasis on dwarf novae, their outburst mechanisms, and observational diagnostics of accretion disk evolution. I also outline the motivation and objectives of ongoing work focused on studying the evolution of accretion disks in eclipsing dwarf novae.

Investigating the Chautang-Drishadvati-Harappan connection

Date

2025-12-30

Speaker

Aditya Vikram Mishra

Venue

Ground Floor Lecture Hall

Abstract

Numerous Harappan urban centers have been discovered along the floodplains of Ghaggar and Chautang in northwestern India. These minor seasonal streams could not have supported large settlements in the past. Many believe that these streams occupy the channels of two mighty, perennial rivers of yesteryears - the Sarasvati and the Drishadvati, respectively. Although the timelines of the river Sarasvati's evolution/demise and the nature of its water/sediment sources have been established, very little is known about the river Drishadvati and its connection to the Harappan civilization. My PhD study aims to investigate this question using modern geochronological, geochemical, and isotopic tools. In the seminar, I shall provide a brief overview of my thesis problem.

Geochemical Investigation of Neoproterozoic Bhander Shales: Implications towards Provenance

Date

2025-12-30

Speaker

Deependra Singh

Venue

Ground Floor Lecture Hall

Abstract

The Neoproterozoic Eon, which spanned 1000-538 Ma, marks an important time in crustal history between the break-up of Rodinia and the assembly of Gondwana. To understand the evolutionary history of the Earth’s crust in this time frame, Sedimentary basins act as an excellent natural laboratory by preserving the signature of evolution in the sedimentary rocks. The Vindhyan basin of India is such an archive which provides an opportunity to investigate sediment provenance and basin evolution by the analysis of its sedimentary rocks. So, to understand the provenance of the sediments of this vast basin becomes important to characterize the source of these sediments and to infer the tectonic setting and climatic conditions of the source region at that time. In this talk, I will discuss the basic idea of the sedimentary provenance of Neoproterozoic shales of the Bhander group from the Rajasthan section of the Vindhyan Basin. I will also present some preliminary results of my work and my future plans in this direction.

Understanding the Spectral Energy Distribution (SED) of Blazars

Date

2025-12-29

Speaker

Ashad Ahmad

Venue

113/114, Thaltej Campus

Abstract

Relativistic jets in blazars are sites of extreme plasma conditions, efficient non-thermal particle acceleration, and broadband radiation extending from radio to very-high-energy γ-rays. Their spectral energy distributions (SEDs) exhibit a characteristic double-humped structure, commonly interpreted as synchrotron emission at low energies and inverse-Compton or hadronic processes at high energies. The observed luminosities, rapid variability, superluminal motion, and one-sidedness of the jet impose strong constraints on the size, speed, and geometry of the emitting region, requiring relativistic beaming and compact dissipation zones within the jet. Leptonic and hadronic emission models are commonly employed to reproduce blazar SEDs and multi-wavelength variability, but these models typically rely on simplified assumptions for the underlying non-thermal particle energy distributions. Such non-thermal spectra cannot arise from purely thermal processes, indicating the presence of efficient particle acceleration operating in relativistic jet environments.

Role of ocean anoxia in the Permian–Triassic crisis: Evidence from geochemical and isotopic data

Date

2025-12-26

Speaker

Nilima Mishra

Venue

Ground Floor Lecture Hall

Abstract

The Permian–Triassic boundary (“Great Dying”), the most severe mass extinction in Earth's history, was accompanied by extreme perturbations in ocean oxygenation. Reconstructing ocean redox conditions during this event is critical for evaluating the vulnerability of modern oceans and for distinguishing reversible environmental stress from tipping-point behavior in Earth’s life-support system. In this talk, I will discuss how molybdenum isotopic geochemistry provide a powerful framework for reconstructing changes in global ocean redox conditions across the Permian–Triassic boundary.

Assessing environmental microplastics using FTIR

Date

2025-12-26

Speaker

Maitri Maheshwari

Venue

Ground Floor Lecture Hall

Abstract

Microplastics are the fragmented particles of plastic debris that are generated from degradation or waste release, contaminating our environment. Found in mountains, polar caps, and deep-ocean trenches, MPs are proving their ubiquitous nature with every new study. To accurately assess their presence and effects on our ecosystems, various analytical techniques have been developed, of which Fourier Transform–Infrared Spectroscopy (FTIR) is widely employed. In the talk, I will discuss this non-destructive and convenient method and how it has made MP analysis easier. Furthermore, certain limitations need to be addressed, and complementary solutions are necessary to achieve reliable results.

Stellar Streams in the Milky Way's Halo

Date

2025-12-26

Speaker

Arvind

Venue

113/114, Thaltej Campus

Abstract

The Milky Way galaxy is our home galaxy, hosting our solar system and billions of other stars. One of the key questions in galactic astronomy is to understand the formation and evolution of galaxies. As we are part of the Milky Way, it provides us with a unique opportunity to study its components in great detail, allowing us to gain a deeper understanding of how galaxies form and evolve in general. According to the cosmological paradigm, galaxies form through hierarchical accretion of lower-mass galaxies. The recently discovered stellar streams in the Milky Way's halo are direct evidence of these merger events. Stellar streams form due to the tidal disruption of a globular cluster or dwarf galaxy that orbits the Milky Way. In this talk, I will discuss about the stellar streams, how they are detected, and what information we obtain from their spectroscopic follow-up. I will also discuss about the target selection for the spectroscopic observation of the stream stars. Determining the age of the stellar streams is crucial because they serve as a record of the Milky Way's growth, revealing its merger history and assembly timeline.

Spectro-Polarimetry of Symbiotic Star

Date

2025-12-24

Speaker

Sube Singh Gurjar

Venue

113/114, Thaltej Campus

Abstract

Symbiotic stars are interacting binary systems composed of a cool red giant and a hot white dwarf. Material is transferred from the giant to the dwarf through a stellar wind or in some systems,via Roche-lobe overflow. An intriguing fact of symbiotic systems is their extremely low known population; only around 300 such system are known against their predicted population of around 300,000 in our Galaxy. Moreover,these exhibit unique emission features at 6825 Å and 7082 Å, which are caused by the Raman-scattering of O VI doublet at 1032 and 1038 Å. As these features are a result of scattering, they show polarization signatures and hence can be used to probe the morphology and kinematics of the systems. We plan to undertake a long term spectro-polarimetic observational study of such systems, wherein any temporal variability of these Raman scattered features would be explored using spectro-polarimetric observations from ProtoPol instrument on PRL 2.5m telescope. In addition, we are upgrading the existing MFOSC-P instrument on PRL 1.2m telescope with newer spectro-polarimetric capabilities.

Novel Tools to assess the Health Risks from Outdoor and Indoor Air Pollution

Date

2025-12-23

Speaker

Dr. Vishal Verma

Venue

Ground Floor Lecture Hall

Abstract

The capability of ambient particulate matter (PM) to generate reactive oxygen species (ROS), conveniently called the oxidative potential is proposed as a better metric for relating the PM pollution with health effects. In this talk, I would present our work on the measurement of oxidative potential of ambient and indoor PM. Through these measurements and comparisons, we demonstrate the need for a comprehensive toxicity and health impact assessment of PM emanating from indoor and outdoor sources.

Revealing the State of the Early Intergalactic Medium through 21-cm Signal Analysis

Date

2025-12-22

Speaker

Dr. Raghunath Ghar

Venue

113/114, Thaltej Campus

Abstract

Measurements of the power spectrum of the redshifted 21-cm signal from the Epoch of Reionization (EoR) provide crucial insights into the ionization and thermal states of the intergalactic medium (IGM) and depend sensitively on the nature of the early radiation sources. Recent upper-limit constraints from SKA precursor experiments such as MWA, HERA, and LOFAR have already begun to exclude several extreme reionization models (e.g., Ghara et al. 2020, 2021). In these models, the 21-cm signal fluctuations are primarily driven by rare, large ionized or emission regions in the early Universe. With forthcoming, more stringent upper limits, particularly from small-scale power spectrum measurements by the SKA, the constraints on the IGM state during the EoR are expected to improve significantly. In this presentation, I will discuss which reionization scenarios and IGM conditions are likely to be ruled out first with SKA observations. I will also summarize the current understanding of the IGM properties during the EoR based on results from ongoing 21-cm signal experiments.

Size-resolved Sources, Composition and Optical Characteristics of Brown Carbon Aerosols

Date

2025-12-16

Speaker

Garima Verma

Venue

Ground Floor Lecture Hall

Abstract

Atmospheric aerosols are critical component of the Earth's climate system and a dominant factor in urban air quality. However, their precise impact on climate and human health is one of the largest uncertainties in modern atmospheric science (IPCC, 2021). Organics are the least studied components in ambient aerosols because of their multiple natural and anthropogenic origins, multifarious chemical composition, and complex formation mechanisms (Andreae and Gelencsér,2006). Brown carbon (BrC), the light absorbing fraction of organic carbon (OC), exerts vital effects on climate change as well as human health. BrC optical properties and radiative forcing effects as a function of aerosol size, which would provide direct evidence as to how important is BrC in driving aerosol climate forcing over Indian megacities. Size-segregated studies offer critical insights into distinct sources and formation pathways that are often obscured in bulk measurements. Understanding of sized aerosols is therefore necessary to comprehend their chemical reactivity, atmospheric lifetime, and impacts on human health and climate.

N₂ Fixation in Inland Water Ecosystem

Date

2025-12-16

Speaker

Md. Fahad Alam

Venue

Ground Floor Lecture Hall

Abstract

We know that the atmosphere is composed of approximately 78% nitrogen, but it is inaccessible to most organisms due to the inert nature of N₂ gas. In that case, N₂ fixation plays a role in transforming this N₂ gas into a bioavailable form. There are a lot of Studies are happening on N₂ fixation in the world and in PRL, also, but Most are in marine ecosystems. Here, I will discuss the inland water ecosystem, as inland and coastal waters cover less than 10% of Earth's surface area, yet they can contribute 15-20% to the global nitrogen budget, which was previously underestimated. I will talk about the water column and benthic N₂ fixation in the inland water ecosystem.

Marine Microbes at the Air–Sea Interface: From SML Ice-Nucleating Bacteria to Microbial Aerosols in the Indian Ocean

Date

2025-12-08

Speaker

Prof. Koji Hamasaki

Venue

Room no. 469, THEPH Division Seminar Room

Abstract

Sea-spray aerosols (SSA) are a major natural source of cloud condensation nuclei (CCN) and ice-nucleating particles (INPs), yet the microbial drivers behind their production and variability remain poorly constrained. The sea-surface microlayer (SML), enriched in organic matter and microorganisms, acts as a selective interface that promotes the transfer of microbe-associated particles to the atmosphere. In this talk, I present two complementary studies that reveal a consistent role of specific marine bacterial lineages—particularly Flavobacteriia and Gammaproteobacteria—in shaping the composition and cloud activity of SSA. First, cultivation-based experiments in a coastal inlet of Japan identified SML bacteria from these groups exhibiting heat-labile, protein-associated ice-nucleating activity above –15 °C, demonstrating their potential as INP sources. Second, ocean-basin-scale microbial profiling during the research cruise across the Bay of Bengal and southeastern Indian Ocean showed that these same taxa are selectively aerosolized from particle-associated fractions, whereas coarse aerosol particles over the Bay of Bengal were more influenced by terrestrial intrusions. This highlights strong ecological and atmospheric controls on which marine microbes enter the air. Together, our findings indicate that microbe-rich SML communities—especially Flavobacteriia and Gammaproteobacteria—represent dynamic contributors to cloud-active aerosols, underscoring the need to integrate microbial ecology into predictions of ocean–atmosphere climate feedbacks. About the speaker: Professor Koji Hamasaki's research is focussed on understanding the microbial diversity and functions within surface ocean ecosystems and their critical roles in biogeochemical cycles. His group is notably recognized for pioneering studies on "actively growing bacteria" in natural seawater, employing advanced bromodeoxyuridine (BrdU) incorporation methods to investigate various metabolic processes, including bacterial photosynthesis, nitrogen fixation, and organic sulfur degradation. More recently, his research has concentrated on the specific role of microbial activity at the air-sea interface and its direct influences on climate processes.

Multiple Emission-Line Diagnostics of the Accretion Process in Young Stars

Date

2025-12-04

Speaker

Kushagra Srivastav

Venue

113/114, Thaltej Campus

Abstract

Young stars consist of a prestellar core, a circumstellar disk, and an envelope. Material from the envelope accretes to the disk, and through angular-momentum loss or removal, disk material is transported onto the central star. Circumstellar disks are therefore central to both stellar growth and planet formation, making them crucial for understanding the early stages of stellar evolution. In low-mass pre-main-sequence stars, accretion proceeds through magnetospheric funnels that channel disk material onto the stellar surface, generating accretion shocks that result in an excess emission in the UV region and strong emission lines. Classical T Tauri stars (CTTSs) show highly variable accretion across multiple timescales. The origins of this variability remain unknown. In this seminar, I will present a detailed analysis of a classical T Tauri star using multiple emission-line diagnostics to investigate its accretion properties and discuss various line diagnostics related to star-disk interaction processes.

The Evolution of Granite-Greenstone Belts of the Western part of Dharwar Craton, Dharwar Craton, South India

Date

2025-12-02

Speaker

S V Balaji Manasa Rao

Venue

Online

Abstract

The evolution of granite-greenstone belts within the Western Dharwar Craton (WDC), a Paleoarchean-Neoarchean crustal accretion, represents the major Archean records of Early Earth. In this contribution, an integrating field relationships-whole-rock geochemistry (major/trace elements, REE patterns), and isotope systematics (Sm-Nd, Lu-Hf) depict an initial TTG-komatiite formation at 3400-3300 Ma linked to juvenile mantle inputs and elevated geothermal gradients, and a mixed tectonic setup. Subsequently, the dome-and-keel architectures emerge through subduction and plume tectonics represented by Sargur Group volcanics (~3.3 Ga), indicating high mantle potential temperatures and distinct tectonic manifestation of Archean Earth. While the younger Bababudan (~2.9 Ga) and Chitradurga (~2.7 Ga) greenstones hosting volcano-sedimentary assemblages reflect back-arc volcanism atop stabilised TTG basement, with two phases of 3.0Ga and 2.6 Ga. The Isotopic U-Pb zircon and radiogenic isotope data reveal episodic crustal growth, contrasting WDC's stable, thick (~42-51 km) core with major growth events at 3.35-3.25Ga, including TTG and Komatiitic Volcanism. Vertical tectonics dominate over nascent subduction, underscoring plume-driven nucleation of proto-cratons globally. Therefore, the eventual formation of granite greenstone belts of Western Dharwar Craton from a wide early Earth time window and proxies to investigate the sequential evolution of Archean cratonic units.

Propagation of Solar Energetic Particles in the Heliosphere

Date

2025-11-27

Speaker

Ritik Dalakoti

Venue

113/114, Thaltej Campus

Abstract

Solar Energetic Particles (SEPs) are charged particles with energies ranging from keV to several GeV, accelerated during solar flares and CMEs. Understanding SEPs is crucial for space weather. These particles generally follow the large-scale interplanetary magnetic field, however, heliospheric magnetic turbulence repeatedly scatters them. This scattering governs SEP propagation, and diffusion parameters such as the parallel diffusion coefficient quantify the strength of diffusion along magnetic field lines. By combining X-ray spectral observations from the Solar X-ray Monitor (XSM) onboard Chandrayaan-2 with particle flux measurements from multiple spacecraft, and by modelling the particle propagation event, we experimentally determine the SEP diffusion coefficient.

What controls the oxygen isotope–salinity relation in the northern Indian Ocean?

Date

2025-11-25

Speaker

Dr. Arvind Singh

Venue

Ground Floor Lecture Hall

Abstract

Seawater oxygen isotopic composition (δ18O) and salinity show a near-linear covariance, forming the basis of widely used δ18O–S relationships. These relationships are often applied to reconstruct past salinity in the ocean from foraminiferal δ18O, yet the associated uncertainties can be large, with errors in inferred salinity reaching >50%. Much of this uncertainty stems from the limited availability of high-quality modern seawater δ18O measurements and an incomplete understanding of the processes that shape this relationship. In this talk, I will present a comprehensive modern seawater δ18O dataset generated at PRL, and discuss how it advances our understanding of the controls governing the δ18O–salinity relationship in the northern Indian Ocean.

Quasiclassical electron transport in topological Weyl semimetals

Date

2025-11-20

Speaker

Azaz Ahmad

Venue

online link: https://imeet.vconsol.com/join/8617443886?be_auth=MDk0MzY2

Abstract

Weyl fermions bridge geometry, topology, and physics, appearing as excitations in Weyl semimetals (WSMs) with unique electronic properties. This seminar will explore chiral anomaly (CA) in WSMs, primarily through longitudinal magnetoconductance (LMC) and the planar Hall effect (PHE). While intervalley scattering is known to reverse LMC, we identify a new mechanism: a smooth lattice cutoff induces nonlinear effects leading to negative LMC. Using a tilted Weyl fermion model, we map phase diagrams to diagnose CA signatures [1]. Strain, acting as an axial magnetic field, introduces a ‘strong sign-reversal’ in LMC, distinct from external fields requiring intervalley scattering. The interplay of external and chiral gauge fields enriches LMC phase diagrams, and we predict distinct strain-induced features in PHE [2]. Extending to nonlinear transport, we develop a theory for the chiral anomaly-induced nonlinear Hall effect (CNLHE), revealing nonmonotonic conductivity in WSMs and a contrasting quadratic dependence in spin-orbit coupled metals [3]. Finally, we generalize CA to pseudospin-1 fermions, showing distinct transport signatures and enhanced sensitivity to internode scattering [4]. These findings provide a unified framework for diagnosing chiral anomaly in diverse chiral quasiparticles, guiding future experimental studies.

Monte Carlo Sampling for Wave Functions Requiring (Anti)Symmetrization

Date

2025-11-18

Speaker

Dr. Ajit C. Balram

Venue

Theory seminar room no: 469

Abstract

"Many strongly correlated states, such as those arising in the fractional quantum Hall effect and spin liquids, are described by wave functions obtained by dividing particles into multiple clusters, constructing a readily evaluable wave function in each cluster, and (anti)symmetrizing across these clusters. We introduce a method to compute quantities such as energies and correlators, using Monte Carlo simulations for these states. Our framework overcomes the factorial scaling of explicit (anti)symmetrization, allowing for studies of systems beyond the reach of exact diagonalization.References: [1]. A. Ahmad et al., Phys. Rev. B 103, 115146 (2021). [2]. A. Ahmad et al., Phys. Rev. B 107, 144206 (2023). [3]. A. Ahmad et al., Phys. Rev. B 111, 035138 (2025). [4]. A. Ahmad et al., Phys. Rev. B 112, 045135 (2025). "

Random encounters in asteroseismology and their impact on a scientific career

Date

2025-11-18

Speaker

Dr. Peter De Cat

Venue

113/114, Thaltej Campus

Abstract

As a little boy, I was already fascinated by the magnificent light show of the twinkling stars in the night sky. My scientific career started almost 30 years ago when, as a physics student at KU Leuven (Belgium), I prepared my master's thesis under the supervision of Conny Aerts. Thanks to her enthusiasm, I started to look into asteroseismology, where the stars reveal the secrets of their hidden interior through the way they vibrate. In this presentation I would like to demonstrate how my interest in stellar pulsations in combination with a few random encounters have led to the two projects that I consider my greatest scientific achievements to date, namely the close collaboration with colleagues from both China (via the LAMOST-Kepler project) and India (via the BINA project). The strength of these projects will be demonstrated by some scientific results in different domains.

Long term X-ray Spectral study of Seyfert Galaxy Mrk 530

Date

2025-11-17

Speaker

Priyadarshee P. Dash

Venue

113/114, Thaltej Campus

Abstract

Active Galactic Nuclei (AGN) are among the most luminous astronomical sources, powered by accretion of matter onto a Supermassive Black Hole (SMBH). Their X-ray emission arises from the upscattering of optical/UV photons from the accretion disk by a hot corona of relativistic electrons, producing a power-law spectrum, which is modified by absorption and reflection features. In some AGN, an excess of photons above the standard power-law can be observed below the 2 keV energy range, termed as Soft Excess. The origin of this Soft excess is still a matter of debate, and various theories have been proposed to explain this excess emission. The warm corona model attributes this emission to arise from the inverse Comptonizaton of the disk photons in an optically thick, warm (0.1 - 1 keV) corona. Alternatively, the blurred ionized reflection scenario explains the soft excess to be a result of the relativistic blurring of the reprocessed emission from the disk due to the effects of strong gravity near the SMBH. More recently, hybrid models combining both warm Comptonization and ionized reflection components have also been proposed.

Supercurrent detection of Majorana-mediated quantum-phase transitions

Date

2025-11-13

Speaker

Dr. Debika Debnath, PRL

Venue

Theory seminar room no 469

Abstract

"We study the experimental signatures of the quantum phase transition (QPT) through the supercurrent probed via scanning tunneling microscopy (STM) to a spin-polarized adatomic impurity which is embedded on a superconductor, giving rise to the non-degenerate Yu-Shiba-Rushinov (YSR) state. We consider the YSR as a controllable state by the adatom's rotational angles ($\zeta, \theta$) and the adatom is coupled to the two end-mode Majoranas. Recent work by Awoga et. al. [1] has shown that controlling the coupling between the YSR and Majorana states through the adatom rotation, can change the parity of the quantum states by modifying the effective ground state energies of both the YSR and Majoranas, which leads to QPT. However, high-precision measurements are elusive for the predictions of the QPT points. Therefore, in this work, we calculate the supercurrent through the YSR-Majorana coupled state and find the jump in the supercurrent at the topological QPT points (i.e. the critical YSR-Majorana coupling strengths), which establishes the supercurrent as an experimental signature of the QPT in our model superconducting junction. We have also investigated the effects of the strong tunnelling and finite temperature on the QPT via the supercurrent calculation. In addition, our result shows that control over the Shiba energy may induce a '0-\pi' phase transition to the topological supercurrent. References: [1] F. Pientka, L. Glazman and F. Von Oppen, Phys. Rev. B 88, 155420 (2013). [2] O. A. Awoga, I. Ioannidis, A. Mishra, M. Leijnse, M. Trif, and T. Posske, Phys. Rev. Res. 6, 033154 (2024)."

Seasonal Variability of Water Vapor Dynamics in the Semi-Arid Region of Western India - revelations from isotopic investigation at Mt. Abu, Rajasthan.

Date

2025-11-11

Speaker

Mr. Virendra R Padhya

Venue

Ground Floor Lecture Hall

Abstract

This study presents the first continuous year-long measurement of stable isotopes (d18O, dD, and d-excess) in atmospheric water vapor over semi-arid western India. Continuous in-situ observations captured isotopic variations from daily to seasonal scales to identify key controlling processes. Temporal changes in vapor isotopes are governed by shifts in moisture sources and the influence of recycled moisture, producing a distinct seasonal isotopic baseline. A pronounced isotopic depletion precedes rainfall events by several days, suggesting its potential as a precursor to precipitation. A sharp isotopic transition observed in late April indicates a major shift in vapor source. The dominant moisture sources—northern and southern Arabian Sea, arid terrestrial regions of Iraq–Iran–Afghanistan–Pakistan, and the wetter eastern landmass of India and the Bay of Bengal—each impart distinct isotopic characteristics, enabling the identification of seasonal vapor origins and their hydrometeorological implications.

Different Ways to Calculate NLP Amplitudes of Scattering Processes

Date

2025-11-11

Speaker

Shuvendu Roy, PRL

Venue

Theory seminar room no: 469

Abstract

The scattering cross-section serves as a bridge between theoretical predictions and experimental observations. However, from a theoretical perspective, the perturbative expansion of the scattering cross-section may break down near the threshold region of certain kinematic variables. To preserve its perturbative behaviour, resummation techniques are employed. There exists a complete resummation theory for LP terms, but not yet for NLP terms. Two approaches are available to compute NLP leading logarithms: the first extends the methods used for colour-singlet production, but this makes the calculation more complex. To avoid these complications, a new technique has been proposed based on the spinor-helicity formalism with shifted spinors. Its application to H + jet production will be reviewed in the discussion, with a short introduction to the previous method along with its disadvantages.

Broad-band temporal and spectral study of Blazars

Date

2025-11-06

Speaker

Avik Kumar Das

Venue

113/114, Thaltej Campus

Abstract

Blazars are the most powerful subclass of active galactic nuclei in which observed emissions are highly Doppler boosted and observable across the entire accessible electromagnetic spectrum ranging from radio to gamma-rays, with diverse variability timescales spanning across minutes to years. The AGN activity level appears to vary on various time-scales. To date, most of the studies have focused mainly on high activity episodes, thereby offering a limited view of the source physical conditions. In our recent work we studied long-term broadband temporal and spectral study of a TeV BL Lac object TXS 0518+211 using 16 years of simultaneous optical, UV, and X-ray observations. In this blazar we find the complex nature of jet-dominated emission processes and suggest for more than one emission zone contributing to the observed broadband spectral energy distribution (SED). In this talk, I shall also present the results based on the photometric and spectroscopic observations acquired from Mt. Abu telescopes.

Nitrogen fluxes and primary productivity in Archaean Ocean

Date

2025-11-04

Speaker

Mr. Janaarthanan P A

Venue

Ground Floor Lecture Hall

Abstract

The most oxidised form of nitrogen - Nitrate (NO3⁻) - serves as an essential and often limiting nutrient for life in the modern well-oxygenated ocean. However, ~3 billion years ago (Archean eon) the Earth’s surface environment and oceans were largely deprived of oxygen. Nitrogen isotopic composition (δ¹⁵N) of sedimentary rocks of that time suggests ammonium (NH4+) dependent anaerobic nitrogen cycling. In an attempt to quantify nitrogen fluxes and productivity in such ammonium-based ecosystem, we have developed a numerical two-box model that simulates Archean nitrogen cycling under ammonium-dependent conditions. In this seminar I will be discussing the results of the model and evaluate the Archean nitrogen isotopic record.

Neutrino oscillations in the plane wave and wave packet formulations

Date

2025-11-04

Speaker

Safana P Shaji

Venue

Theory seminar room no: 469

Abstract

Starting with the theoretical development of neutrino oscillations from plane wave to wave packet formulation, the talk aims to provide insight into the quantity of decoherence, which outlines the wave packet separation. The comparison of oscillated and decohered events is carried out through the lens of Jiangmen Underground Neutrino Observatory (JUNO) experiment, within which we delve into the mass hierarchy and theta12 sensibilities.

Resurrection of Elements in the Milky Way: A MCMC Recipe

Date

2025-10-31

Speaker

Antariksha Mitra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The formation and chemical evolution of the Milky Way are traced through the continuous cycle of stellar birth, death, and enrichment, wherein each generation of stars contributes to the resurrection of elements in the interstellar medium. In this work, we present a Monte Carlo Markov Chain (MCMC) framework developed to model the Galactic Chemical Evolution (GCE) of 83 isotopes spanning 32 elements, employing updated stellar yields. The MCMC approach enables efficient sampling of the complex, multi-dimensional parameter space governing the Galaxy’s star formation rate, initial mass function, and supernova contributions, thereby constraining these parameters against observed elemental abundance distributions. Our simulation reproduces the observed chemical trends across the various regions of the Milky Way, offering insights into the dynamic interplay between stellar nucleosynthesis and Galactic assembly. The results highlight how the ashes of long-dead stars continually reforge the building blocks of new generations: a recursive process central to both the chemical and structural evolution of our Galaxy.

Planetary Differentiation and Sample Analysis

Date

2025-10-24

Speaker

Prof Amit Basu Sarbadhikari

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

After accretion from dust, gas, and rock colliding and sticking together, Planetary differentiation is the process by which a planet's molten materials separate into distinct layers. Following this early stage of planetary evolution, the differentiation process continues for billions of years and may still be ongoing today, owing to the internal dynamics of each planet. Over the past decade, planetary missions—especially to the Moon and Mars, as well as the growing number of recognized lunar and Martian meteorites — have provided transformational insights into the diversity, composition, and histories of planetary materials throughout the inner Solar System. Yet, despite these new insights, defining a reasonably simple set of criteria that provides some predictive understanding of planetary crustal development remains elusive. This talk will try to showcase the elusive characteristics of our understanding towards planetary evolution through the proxy of extra-terrestrial sample analysis.

On-sky characterization and performance verification of ProtoPol

Date

2025-10-23

Speaker

Arijit Maiti

Venue

113/114, Thaltej Campus

Abstract

ProtoPol is a medium-resolution echelle spectro-polarimeter developed for the PRL 1.2m and 2.5m telescopes at Mt Abu observatory, India. ProtoPol provides a spectral resolution in the range of ∼0.4 - 0.75˚A across various orders in the visible wavelength range of 4000-9600˚A. On PRL 2.5m PRL telescope, an SNR of 10 is achieved for Vmag ∼ 13.5 source in 1 hour of integration time, and its throughput is estimated to be ∼6% including all the contributing factors such as atmospheric transmission, telescope reflectivity, instrument’s optics, CCD efficiency, etc. ProtoPol achieved a linear polarization accuracy ≈ 0.1 − 0.2% in 2 hours of integration time for a source with Vmag ≈ 8. The instrumental polarization is determined to be around 0.1%. Several Science observation campaigns were conducted with ProtoPol to demonstrate the capabilities of the instrument. A sample of Herbig Ae/Be stars, classical Be stars, Symbiotic stars, and AGB/post-AGB stars were observed over the period of one and a half years for their spectro-polarimetry measurements covering various physical mechanisms such as line polarization in Herbig and classical Be stars, polarization in Raman scattered features in Symbiotic stars, as well as continuum polarization in AGB/post-AGB stars to verify the polarization performance of the instrument.

Coastal Groundwater: Effects of Climate Change and Abuse on a Critical Resource

Date

2025-10-17

Speaker

Prof. Willard S. Moore

Venue

Ground Floor Lecture Hall

Abstract

Groundwater is an essential resource for most coastal communities. Abuse of this resource and global sea level rise due to climate warming endanger its sustainability. In this talk, I will discuss less obvious aspects of changing coastal groundwaters. Along some coastlines, excess groundwater mining leads to land subsidence. Combined with global sea level rise, this causes enhanced coastal flooding and saltwater intrusion (SWI) into coastal aquifers. The intrusion of seawater into these aquifers poisons an essential resource. The movement is not one-way. Coastal aquifers are an underground link between the land and sea. Terrestrial freshwater and seawater are constantly mixed and exchanged within these permeable sediments, called subterranean estuaries. The flow of fresh or salty groundwater into the ocean is called submarine groundwater discharge (SGD). SWI radically alters the groundwater chemistry by introducing sulfate, a major ion in seawater and a powerful oxidizing agent. Fresh groundwater has low oxidation capacity due to the low solubility of oxygen. The sulfate in seawater brings 200 times greater oxidation capacity, allowing considerably more carbon to be oxidized. The byproducts of marine carbon oxidation include CO2, nutrients (N, P), sulfide (H2S), dissolved organic carbon and nitrogen, and reduced metals (Fe2+, Mn2+). SGD transports these byproducts of carbon oxidation into estuarine and coastal waters, where they may stimulate biological productivity – sometimes to excess, and deplete dissolved oxygen concentrations through reactions with sulfide and other reduced substances. My focus in this talk will be on the interplay between SWI and SGD and the effects on estuarine and coastal waters. About the speaker: Prof. Willard S. Moore is Distinguished Faculty Emeritus in the School of the Earth, Ocean and Environment at the University of South Carolina, USA. He is an internationally renowned marine geochemist whose pioneering research has transformed our understanding of coastal and oceanic processes through the application of naturally occurring radioisotopes, particularly radium isotopes. Prof. Moore’s work has been instrumental in quantifying submarine groundwater discharge and assessing its role in the transport of nutrients, trace metals, and carbon to the coastal oceans. Prof. Moore has been elected Fellow of both the American Geophysical Union (AGU) and the American Association for the Advancement of Science (AAAS), and is a recipient of the prestigious “Buck” Ketchum Award from the Woods Hole Oceanographic Institution.

Exploring GRB Localisation Capability of Proposed Daksha Mission using Coded Mask Imaging with its Low-Energy Detectors and Their Development.

Date

2025-10-16

Speaker

Ashish Kumar Mandal

Venue

113/114, Thaltej Campus

Abstract

Gamma Ray Bursts (GRB) are short, intense extragalactic gamma-ray flashes. GRBs are of two kinds-long GRBs (burst duration >2 sec) thought to be produced due to core collapse of rapidly rotating massive stars, short GRBs (duration <2 sec) believed to be produced due to merger of binary compact objects like neutron star-neutron star (NS-NS) or black hole-neutron star (BH-NS). Daksha is India’s proposed high-energy transient mission aimed at detecting and characterizing electromagnetic counterparts (EMCs) of gravitational wave (GW) events and GRBs. In its initial configuration, Daksha can localize short GRBs to within 5–10 degrees using a projection method. Daksha’s scientific potential could be greatly enhanced if onboard GRB localization within 1 degree is made possible, which can be potentially achievable using the Coded Aperture Mask (CAM).

Multi-wavelength Variability and Quasi Periodic Oscillations (QPOs) in Blazars

Date

2025-10-13

Speaker

Prof. Alok Gupta

Venue

113/114, Thaltej Campus

Abstract

This is the age of multi-wavelength (MW) time domain astronomy in which the transient astronomical sources are of great interest due to their rapid change in flux, spectra and polarization. Simultaneous MW observation of a particular transient source over an extended period of time has importance to understand the emission mechanism in different electromagnetic (EM) bands. Blazars are among one of the most favourite astronomical transient objects, because they emit radiation in the complete EM spectrum, and their flux, spectra and polarization are highly variable.

Interplanetary Dust and Its Measurement in Solar System

Date

2025-10-10

Speaker

Prof. Jayesh Pabari

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Our solar system is immersed in a thin cloud of Interplanetary Dust Particles (IDPs). The dust is an important constituent in formation of solar system and found everywhere. The IDP may originate from sources like Asteroid belt, Kuiper belt or comets and evolve dynamically under the influence of various forces. Although, there are some measurements of IDP near Earth and also, in the interplanetary space; there are no measurements of IDP at other inner planets. The entering dust particles in a planetary object can affect it in different ways. During the seminar, the results of IDP flux in inner solar system will be presented. The Dust EXperiment (DEX) was flown recently using POEM 3 on PS4 of PSLV C-58 (XPoSat) mission to understand dust particles in the Earth orbit. From the dust observations in near Earth orbit, the DEX was found working successfully in space. The results obtained from DEX will be also be presented

Search for dark matter over a wide mass range: using JWST and neutrino telescopes to search for non-gravitational signatures of dark matter

Date

2025-10-10

Speaker

Dr. Ranjan Laha

Venue

Theory seminar room no: 469

Abstract

"I will discuss two different ways to search for dark matter (DM). First, I will discuss how we used JWST data to probe eV-scale QCD axion DM or axion-like particle (ALP) DM decaying into two photons. This will produce a distinct line signature in the spectroscopic observations made by JWST. Using the latest NIRSpec IFU spectroscopic observations from JWST, we put some of the strongest bound on the photon coupling for QCD axion/ ALP DM in the mass range between 0.47 and 2.55 eV. In the second part of my talk, I will discuss how neutrino telescopes like IceCube and Super-Kamiokande can probe DM - electron scattering. DM can get captured inside the Sun due to DM - electron scattering and it can annihilate into neutrinos and anti-neutrinos. Using latest neutrino measurements, we set world leading limit on DM - electron scattering for DM masses between 10 GeV to about 10^5 GeV."

Role of picophytoplankton in the carbon cycle of the northern Indian Ocean

Date

2025-10-07

Speaker

Dr. Sipai Nazirahmed

Venue

Ground Floor Lecture Hall

Abstract

Picophytoplankton are vital drivers of marine biogeochemical cycles and serve as indicators of ocean productivity, ecosystem health, and climate change. As the smallest single-celled phytoplankton, they play a crucial role in ocean ecosystems, being globally recognized as major primary producers and significant contributors to the oceanic carbon stock. Despite their ecological importance, their role is often underestimated, particularly in the northern Indian Ocean—an oceanic region characterized by high environmental variability and dynamic biogeochemical processes. In this seminar, I will present the results that aimed to quantify the abundance and carbon biomass of picophytoplankton and to assess the influence of regional physicochemical parameters on their spatial distribution and ecological role in the northern Indian Ocean. Our findings demonstrate that the contribution of picophytoplankton carbon biomass to the total particulate organic carbon (POC) pool was substantial in both the Arabian Sea and the Bay of Bengal. This underscores their significant, yet often overlooked, role in supporting the regional biological pump and influencing carbon fluxes.

Improved Constraints on Coexisting WIMP/ FIMP Dark Matter and Primordial Black Holes

Date

2025-10-06

Speaker

Dr. Prolay Krishna Chanda

Venue

Theory seminar room no: 469

Abstract

Particle dark matter and primordial black holes (PBHs) may coexist with significant cosmic abundances, each contributing to the observed dark matter density ΩDM. Large populations of PBHs with ΩPBH ∼ ΩDM are strongly constrained for masses above 10−11M⊙. If the WIMP/ FIMP particle dark matter has interactions with the Standard Model, new constraints arise due to pair-annihilations that are enhanced by the PBHs, resulting in dark matter indirect detection constraints on fPBH — these bounds rule out the mixed WIMP-PBH dark matter for velocityindependent cross-section, ⟨σv⟩ ∼ 10−26cm3/s. In this talk, we will discuss how a particle DM candidate with a velocity-dependent cross-section relaxes these bounds. We also derive the bounds on mixed scenarios in which PBHs coexist with particle dark matter whose relic abundance is set via freeze-in (‘FIMPs’). We show that while the restrictions on fPBH are less constraining for FIMPs than WIMPs, modest bounds still arise for large classes of models.

Investigating Lunar Subsurface Water Ice through Neutron Leakage and Gamma-Ray Continuum Flux

Date

2025-10-03

Speaker

Ms Shipra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Lunar volatiles, including water ice, are considered to be preserved in cold traps or buried beneath the surface layer near the poles. Understanding their distribution and abundance is critical for advancing knowledge of lunar evolution and for supporting future exploration activities. Neutron and gamma-ray spectroscopy provide key tools for this purpose, as subsurface hydrogen abundance can be inferred to depths of up to 1 m from measurements of neutron leakage flux and gamma-ray continuum flux from the Moon. In this seminar, I will discuss the lunar leakage neutron and gamma continuum flux induced by galactic cosmic rays interacting with the lunar surface, as well as their dependence on subsurface hydrogen abundances, using Monte Carlo simulations. The effects of temperature and compositional variation on neutron leakage flux are examined. The sensitivity of the leakage neutron intensity to the depth profile of subsurface water ice within the top 1 m of soil will also be discussed.

Geochemical Insights into the formation of Andaman Ophiolite during Subduction Initiation

Date

2025-09-30

Speaker

Mr. G N S Sree Bhuvan

Venue

Ground Floor Lecture Hall

Abstract

Ophiolites are fragments of the oceanic lithosphere exposed on land. It is essential to understand the magmatic history of an ophiolite, which holds geochemical clues to its tectonic setting. Recent research on the Neo-Tethyan ophiolites suggests that the ophiolite formation is related to subduction, likely during subduction initiation. Andaman ophiolite, exposed on the forearc of the Andaman subduction zone in the Andaman Islands, India, is a dismembered ophiolite containing mantle peridotites, cumulate gabbros, intrusive plagiogranites, massive and pillow basalts, with later dyke intrusions. Although the age of the Andaman ophiolite is well constrained to be 98±8Ma, its formation remains debated, with views suggesting a diverse range of tectonic settings. Hence, it presents an opportunity to test the hypothesis of ophiolite formation during subduction initiation. Using bulk rock major and trace element abundances and Sr-Nd isotopic compositions, I will present new inferences on the origin of the Andaman ophiolite.

Stable and Interpretable Jet Physics with IRC-Safe Equivariant Feature Extraction

Date

2025-09-25

Speaker

Deepanshu Srivastava, PRL

Venue

Theory seminar room no: 469

Abstract

"Deep (machine) learning has achieved remarkable success in the complex area of QCD (Quantum Chromodynamics) jet classification using low-level calorimeter data from high-energy physics detectors. However, a significant challenge persists: understanding what these models learn and how their features correlate with established QCD observables. Improving interpretability is essential for building robust and trustworthy machine learning tools in any of their applications. To tackle this challenge, we present a case study using graph neural networks for quark–gluon discrimination, systematically incorporating physics-motivated inductive biases. In particular, we design message-passing architectures that enforce infrared and collinear (IRC) safety, as well as additional symmetries, including E(2) and O(2) equivariance in the rapidity–azimuth plane. Using simulated jet datasets, we compare these networks to unconstrained baselines in terms of classification performance, robustness to soft emissions, and internal feature organisation. Our findings demonstrate that embedding symmetry and safety constraints not only improve robustness but also ground network representations in established QCD structures, providing a principled path toward interpretable deep learning in collider physics. "

Amplifying muon-to-positron conversion in nuclei with ultralight scalar dark matter

Date

2025-09-22

Speaker

Dr. Purushottam Sahu

Venue

Theory seminar room no: 469

Abstract

"I will present an analysis of the lepton-number and lepton-flavour-violating process of muon-topositron conversion µ − +N → e + +N ′ , in the presence of an ultralight scalar dark matter (ULSDM) field which couples to neutrinos. The ULSDM contributes to the effective off-diagonal Majorana mass mµe, therefore amplifying the rate of muon-to-positron conversion to experimentally observable levels. Using existing bounds from SINDRUM II, COMET, and Mu2e experiments, we derive constraints on the flavour-off-diagonal couplings of neutrinos to ULSDM . Our work reveals that upcoming experiments can provide stronger sensitivity to these new couplings than bounds arising from cosmological surveys and terrestrial experiments.

MXene in LEO: A Technology Demonstration of Nano-Biomaterial Devices in the ISS with Axiom 4 Mission

Date

2025-09-18

Speaker

Dr. Shreyas Srivatsa

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

MXenes are a family of two-dimensional nanomaterials made of metal carbides/nitrides/carbonitrides. The inorganic compound of MXenes, first reported in 2011 (titanium carbide, Ti3C2TX-MXene), has found various terrestrial applications like supercapacitors, sensors, electromagnetic shielding, chemical sensors, wearable devices, biomedical and implantable devices, multifunctional coatings, etc. Some of the unique properties of MXenes (particularly, Ti3C2TX-MXene) are film-forming ability, hydrophilic behavior, low electrical resistivity, good elasticity, field-electron mobility of, and fast dynamic response behavior. The possibility of hundreds of unique stoichiometric MXene combinations, reported to date, results in achieving wide tunability of physical and chemical properties by varying ratios of metal and carbide/nitrides/carbonitrides. After exhaustive testing and validation of the MXene devices in terrestrial environment, the speaker and his team were the first to test the MXene devices with several stratosphere flights from 2022. Building on the results from real environment testing of MXene nanomaterial and its devices, MXene in LEO (MXene Material and Wearable Device Experiments in Low-Earth Orbit Space Habitat) was proposed as part of the IGNIS mission of the European Space Agency and Polish Space Agency, forming a part of the Axiom 4 mission. MXene in LEO is a unique technology demonstration in the low-Earth orbit (International Space Station) using multifunctional nanomaterial (MXene) and sustainable biomaterial (bacterial cellulose) to form nano-biomaterial devices for human health monitoring in space. The first objective of the experiment was to test the environmental stability of MXene nanomaterial inside the space station. The second objective was to test the possibility of detecting hand movement and pulse of the human subject wearing the MXene wristbands in the space station. With the accomplishment of both objectives, the technology demonstrator provides a foreground for wider usage of MXene nanomaterials in space applications and their direct impact on terrestrial activities.

Looking under the lamppost for dark neutrino masses

Date

2025-09-18

Speaker

Dr. Manibrata Sen

Venue

Theory seminar room no: 469

Abstract

The origin of neutrino masses remains one of the most pressing open questions in particle physics. While conventional approaches rely on extending the Standard Model with heavy fields or new symmetries, an alternative idea has recently emerged: neutrino masses may arise through refraction in the background of ultralight dark matter. In this framework, neutrinos acquire dynamic, effective, time-varying masses as they propagate through a coherent oscillating field, leading to distinctive imprints on oscillation experiments, beta-decay searches, and astrophysical neutrino signals. In this talk, I will introduce the basic mechanism of refractive neutrino masses and discuss its phenomenological consequences for laboratory, astrophysical, and cosmological probes and highlight how upcoming experiments may provide the first opportunities to test this novel connection between neutrinos and the dark sector.

Exploring Fluvial activity around the circum-chryse basin on Mars

Date

2025-09-12

Speaker

Rishav Sahoo

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Chryse Planitia is an asymmetrical basin centred at approximately 45oW and 24oN, about 2000 km northeast of Valles Marineris. It has a diameter of ~1600 km and is 2-3 km below the mean Mars elevation. This basin receives deposits from several major outflow channel systems. Two principal groups of channels terminate in this basin. The first originates from chaotic terrains near the eastern end of Valles Marineris and flows northward for over 1000 km into the southern part of the basin. This group includes Ares Vallis, Tiu Vallis, Simud Vallis, and Shalbatana Vallis. The second group, dominated by Kasei Vallis, enters the basin from the west. As such, Chryse Planitia receives sediment and water input from two widely separated source regions spanning over 2500 km. In this seminar I will discuss the interaction of the major fluvial channels with the rim of Chryse Planitia basin. I will be discussing a new method for estimating the discharge, volume and timescales of fluvial activities around the circum-chryse region. This new method involves simulation for Unsteady flow analysis through which I would be exploring one of the largest dam-break scenarios in the solar system.

Accelerator Mass Spectrometry - Current Understanding, Recent advancements and the way forward

Date

2025-09-09

Speaker

Mr. A Shivam

Venue

Ground Floor Lecture hall

Abstract

Accelerator Mass Spectrometry (AMS) has revolutionized ultra-sensitive radio isotopic analysis across scientific disciplines. PRL Houses state-of-the-art 1MV Accelerator Mass Spectrometer for analysis of radioisotopes like 14C, 10Be and 26Al. This seminar explores the current understanding of AMS principles, highlights current status and recent developments in PRL-AURiS (PRL-Accelerator Unit of Radioisotope Studies) and the session will conclude with perspectives on future directions, exploring the possibilities of new isotopic targets, and broader interdisciplinary impact. Attendees will gain a comprehensive overview of AMS, its functioning principles, its evolving capabilities, and critical developments shaping the field. The seminar shall be in most general language - and shall be able to cater to a wide audience working in any field.

Linear and Nonlinear Excitations in Rotating Dusty Plasmas across Coupling Regimes

Date

2025-09-08

Speaker

Dr. Prince Kumar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Dusty plasmas consisting of dust particles, electrons and ions, can be found in various states of matter (solid, liquid, and gaseous) [1-3]. They, therefore, cover a broad range of parameter space relevant to both astrophysics as well as laboratory environments. Studies of the collective excitations in dusty plasmas provide valuable insights into their static and dynamic properties, as well as how these excitations can be controlled for practical applications [4-7]. For example, investigations of these excitations in the strongly coupled limit can be relevant to ion trap systems where the phonon mode spectrum is manipulated to enhance quantum gate performance efficiency [8]. From an astrophysical perspective, recent dusty plasma experiments have observed nonlinear excitations, such as pinned, precures solitons, generated by a moving charged obstacle [9]. These observations motivate the idea of indirect detection of space debris in the ionosphere through such structures[10]. In this talk, I first discuss magnetoplasmon excitations in rotating dusty plasma equilibria that can be generated in the absence of non-conservative fields [1-2]. These magnetoplasmon signatures have been observed in the absence of a real magnetic field across a wide range of dusty plasmas parameter [1]. Then, I address the nonlinear excitations such as Korteweg-De Vries (KdV) Soliton, pinned, precursor solitons in non-rotating dusty plasmas. The characterization of KdV Soliton structures is presented in details under the existing models to test their reliability, and new models are proposed to overcome their limitations [6-7]. Finally, I discuss the pinned and precursor solitons, which are induced in the medium by a moving charged source, appearing at and ahead the source, respectively, under specific Mach number values. The potential applications of these structures for detecting space debris in the lower Earth orbit (LEO) region of the ionosphere are also outlined.

From Suppression to Reprogramming: Precision Nanomedicine for Rheumatoid Arthritis and Beyond

Date

2025-09-02

Speaker

Dr. Ashutosh Kuma

Venue

Ground Floor Lecture Hall

Abstract

Chronic inflammatory diseases, including rheumatoid arthritis and certain cancers, remain among the most challenging conditions to treat. Conventional therapies often work broadly across the body, suppressing the immune system in ways that can cause serious side effects and fail to provide lasting benefit. My lab is pursuing an altered path: nanomedicine designed to bring treatment directly to the source of inflammation. My lab engineer long-circulating lipid nanoparticles, including immunoliposomes, that selectively accumulate in inflamed tissues. These carriers allow us to deliver RNA-therapeutics like siRNA and miRNA, along with anti-inflammatory drugs, precisely where they are needed, reducing systemic toxicity and expanding the therapeutic window. This targeted approach not only calms harmful immune activity but also reprograms immune cells toward reparative states, offering the possibility of rebuilding tissue function rather than merely suppressing disease. Our work addresses multiple levels of immune regulation, including silencing key cytokines, modulating the NF-κB and JAK–STAT pathways, and investigating PAD inhibition to prevent early autoimmune triggers. Beyond treatment, the lab is developing early detection strategies to identify disease before irreversible damage occurs. By tracking biomarkers such as protein modifications driven by PAD enzymes, we aim to capture the earliest molecular signals of autoimmunity. At the same time, we are making efforts to integrate laboratory findings with retrospective patient data to understand how inflammation, comorbidities, and lifestyle factors shape treatment responses. Together, these efforts outline a translational roadmap that links mechanistic insight with clinical application.

Exploration of the Venus and Lunar Ionosphere Using Radio Science Experiments

Date

2025-09-02

Speaker

Dr. Keshav R Tripathi

Venue

ONLINE

Abstract

Venus and the Moon, our two neighbouring celestial bodies, exhibit extreme contrasts in atmospheric conditions. Venus has a neutral density nearly 90 times that of Earth, while the Moon has an almost negligible atmosphere. Despite these differences, both bodies possess significant ionized layers capable of affecting radio signal propagation. This seminar will focus on the characteristics of these ionospheric layers as revealed through radio occultation experiments, with comparisons to Earth’s ionosphere. We will also discuss the implications of these findings for future exploration.

Chandrayaan-3 Pragyan Rover at Shiv Shakti Statio: Findings from APXS In Situ Geochemical Measurements and Contextual Remote Sensing Analysis

Date

2025-08-29

Speaker

Dr. Rishitosh K. Sinha

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Chandrayaan-3 mission is the first successful soft-landing at the Shiv Shakti statio (located at 69.37°S, 32.32°E) in the south polar region of the Moon. During the mission, the Pragyan rover traversed around 103 m on the lunar surface within a single lunar day. Onboard the rover was an instrument called the Alpha Particle X-ray Spectrometer (APXS), which measured the elemental composition of the Moon’s surface. The abundance measurements of major elements supported the widely accepted lunar magma ocean (LMO) hypothesis, which suggests that the early Moon was once covered by a global layer of molten material. In addition to major elements, the APXS also measured the abundance of volatile elements including sodium, potassium, and sulfur at the landing site, which varied in concentrations ranging from 700-2800 ppm, 300-400 ppm, and 900-1400 ppm, respectively. The detailed comparison and analysis of volatile abundances with the measurements in soil samples collected in earlier missions (Apollo 16 and Luna 20) revealed that there is anomalous depletion in sodium and potassium, but enrichment in sulfur in the soils at the Chandrayaan-3 landing site. One possible source of sulfur in lunar soils is Type I Carbonaceous chondrites (CC), which can add approximately 400-1000 ppm of sulfur into the lunar soil. However, this alone cannot explain the excess of 200-400 ppm sulfur observed at the Chandrayaan-3 landing site. In this case, there has to be another source of sulfur that increased its concentration at the landing site. Toward the end of the LMO crystallization stages, around 4.3 Ga ago, the residual molten layer in the lunar mantle became enriched in a mineral called Troilite (FeS), which contains sulfur. Around the same time, a giant impact created the South Pole-Aitken (SPA) basin, which is one of largest and oldest impact basins in the solar system, approximately 2,500 km wide. This massive impact likely excavated this sulfur-rich troilite from the Moon’s interior, when the KREEP (potassium, rare earth elements, and phosphorus) layer was not adequately formed. The subsequent impacts on SPA basin ejecta resulted in further stirring of the materials across the region, possibly redistributing it at the Chandrayaan-3 landing site. To summarize, the Chandrayaan-3 landing site hosts sulfur-rich material from the Moon’s primitive mantle, which was excavated by the SPA basin impact billions of years ago. This makes the Chandrayaan-3 landing site a valuable place for accessing samples from the mantle of the Moon, which is otherwise lacking in the existing lunar collections. These samples would offer a rare opportunity to study about the early evolution of the Moon.

New plasmon-like mode in PdTe2: Raman scattering and memory function study

Date

2025-08-26

Speaker

Dr. Bharathi Ganesh D, PRL

Venue

THEPH Room no: 469 (seminar room)

Abstract

PdTe2 is a 2D material with its bands having a tilted Dirac cone structure. Due to its novel band structure it is touted to have many promising applications. Understanding the low energy excitation of such materials is important and in this direction we reported a new plasmon-like mode emerging at low temperatures (< 100 K) in PdTe2. We support this claim with a phenomenological analysis based on the memory function formalism.

Uranium in the ocean: Inferences on bottom water anoxia during the Last Glacial Period

Date

2025-08-19

Speaker

Prof. Manmohan Sarin

Venue

Ground Floor Lecture Hall

Abstract

The paleo-oceanographic studies suggest that deep ocean was depleted in dissolved oxygen (O2) during the last glacial period (LGP, ~18 kyr BP). Therefore, paleoceanographers have sought a direct tracer for studying the changes in dissolved O2 in the deep ocean during the LGP. Geochemical proxies like redox-sensitive trace elements (Vanadium, Molybdenum, Uranium, Manganese) in bulk sediments have been used to reconstruct the past bottom water environment. Example, in oxic seawater, uranium is present in relatively high concentration as uranyl-carbonate complexes which are highly soluble. Under O2 deficient (anoxic) conditions, uranium can be reduced from U(VI) to a less soluble tetravalent state U(IV), which is particle reactive and gets fixed into the sediments. A geochemical study validating this concept was published in 1993 (‘Geochemical evidence for anoxic deep water in the Arabian Sea during the last glaciation’; Sarkar, Bhattacharya & Sarin; Geochimica et Cosmochimica Acta). The purpose of this seminar is to discuss two recent articles (Geochemical Perspectives Letters 2024 and Marine Geology 2025) using the very same concept/approach published more than three decades ago (PRL study).

Quantum mechanics, decoherence, and quantum-to-classical transition

Date

2025-08-14

Speaker

Prof. Navinder Singh, PRL

Venue

Room no: 469 (Main Campus)

Abstract

This talk is divided into two parts: First part will be an elementary introduction to the theory of decoherence, quantum mechanics, and quantum-to-classical transition. We will discuss how Niels Bohr's idea of the "cut" and the requirement of a classical apparatus for the interpretation of quantum mechanics can be rationalized in the framework of the modern theory of decoherence by Zurek and others. In the second part, we present our results related to the Ovchinnikov-Erikhman theory of decoherence. We point out the problems with this scenario and revise it to apply it to a realistic case of the motion of conduction electrons. Interesting results are obtained. Our results agree with the alternative master equation approach.

Evolution of the Laxmi Basin, Arabian Sea, during the Deccan volcanism

Date

2025-08-12

Speaker

Dr. Sibin Sebastian

Venue

Ground Floor Lecture Hall

Abstract

The Laxmi Basin is a prominent geomorphic feature and a marginal depression in the Northwest Indian Ocean (Arabian Sea). This ~300 km wide basin separates the western Indian continental margin from the Laxmi Ridge (LR), which is believed to be continental. The precise nature of the basin's basement remains controversial, with differing views suggesting it could be either a stretched continental crust with magmatic intrusions related to continental rifting (contemporaneous with Deccan volcanism) or a pre-Paleogene oceanic crust. Additionally, a geochemical study of the basin's igneous basement indicates that these rocks formed in a subduction zone setting. Understanding the crust's nature has implications for the geodynamic events of continental breakup and the formation of the Indian Ocean during the Late Cretaceous. To address this controversy, we conducted geochemical and isotopic studies on basaltic lava samples from this basement, recovered during IODP 355. In this talk, I will present the results of our study and our inferences regarding the crustal nature of the Laxmi Basin.

Lunar Polar Water-Ice: Current Understanding and New Insights from ShadowCam

Date

2025-08-08

Speaker

Ms Sachana A S

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Our understanding of lunar volatiles is significantly improved using multi orbiter data-sets and reanalyzing returned samples. Multiple observational evidences suggest that water-ice is predominantly concentrated within permanently shadowed regions (PSRs) near the lunar poles, which are also the prime targets for future lunar exploration. With the current limitations of observational datasets, the occurrence, content, distribution and source of water-ice in PSRs are yet to be answered. In this work, we used ShadowCam, a high-resolution imaging system aboard the Korea Pathfinder Lunar Orbiter (KPLO) for understanding the PSR morphology. ShadowCam offers unprecedented views into these shadowed terrains, allowing detailed analyses of surface textures and reflectance anomalies that may indicate water-ice presence. Here, I will present the initial results from our analysis using ShadowCam data, investigating surface reflectance behaviour of PSRs from south pole, highlighting the reflectance variations that might indicate the distribution of water-ice at and within different PSRs.

NICER insight into the High-Energy Universe

Date

2025-08-07

Speaker

Dr. Gaurava Kumar Jaiswal

Venue

113/114, Thaltej Campus

Abstract

Since its deployment to the International Space Station in June 2017, the Neutron Star Interior Composition Explorer (NICER) has significantly advanced our understanding of compact objects in the X-ray sky. With exceptional timing and spectral capabilities in the 0.2 - 12 keV range, NICER enables detailed studies of accretion-powered and magnetically driven phenomena. A major focus has been on thermonuclear X-ray bursts -brief, intense explosions caused by unstable burning of hydrogen and helium on neutron star surfaces, which offer key insights into the physics of dense matter. This talk will highlight crucial findings from eight years of NICER observations, covering burst behavior, accretion dynamics, X-ray transients, and magnetar activities. It will also discuss efforts to understand the interaction between compact objects and their optical companions through X-ray and optical observations. Finally, I will present recent updates on the long-term calibration of the JEM-X instruments aboard ESA's INTEGRAL mission and ongoing progress toward establishing the INTEGRAL Legacy Archive.

An overview of compact X-ray binaries

Date

2025-08-06

Speaker

Dr. Gaurava Kumar Jaiswal

Venue

113/114, Thaltej Campus

Abstract

Compact objects represent some of the most extreme environments in the universe. When these dense remnants are part of a binary system, they can draw in matter from their companion stars through a process known as accretion. This transfer of material releases vast amounts of energy, making these systems strong sources of X-rays. Compact X-ray binaries, in which a neutron star or black hole accretes matter from a companion, offer unique opportunities to study energetic processes like accretion dynamics, outbursts, and thermonuclear bursts on neutron star surfaces. This talk will introduce the fundamental concepts behind accretion, compact binaries, and related phenomena, and will highlight why these systems are key to advancing our knowledge of high-energy astrophysics.

Nitrogen loss processes in aquatic ecosystems

Date

2025-08-05

Speaker

Dr. KM Ajayeta Rathi

Venue

Ground Floor Lecture Hall

Abstract

Nitrogen, though abundant in the atmosphere, often limits primary productivity in aquatic ecosystems. These ecosystems play a crucial role in regulating the global nitrogen cycle both by converting inert atmospheric nitrogen into bioavailable forms through dinitrogen fixation and by removing excess reactive nitrogen via microbially mediated loss processes, including denitrification, anaerobic ammonium oxidation (anammox), and, to some extent, dissimilatory nitrate reduction to ammonium (DNRA). However, with increasing anthropogenic nitrogen inputs and climate-driven environmental changes, the efficiency and dominance of these pathways are shifting, with significant implications for ecosystem health, biogeochemical feedbacks, and nitrogen budgets. In this seminar, I will discuss the mechanisms, environmental controls, and experimental approaches used to study nitrogen loss processes in aquatic ecosystems.

Probing Compressed Inert Scalars with Forward Muon Tagging at the Muon Collider

Date

2025-08-05

Speaker

Dr. Chandrima Sen, PRL

Venue

Room no: 469 (Main Campus)

Abstract

The compressed mass spectrum of the Inert Doublet Model (IDM) poses a significant challenge for current collider experiments, as the soft visible decay products and suppressed production rates hinder conventional search strategies. In this talk, I will explore the discovery prospects of such a compressed electroweak sector at a future high energy Muon Collider operating at 10 TeV. Focusing on vector boson fusion (VBF) production of inert scalar pairs, I will demonstrate how forward muon tagging provides a powerful handle to isolate signal events in scenarios where traditional missing energy based searches fail. After reviewing the relevant dark matter and experimental constraints on the IDM parameter space, I will present a detailed collider analysis using both cut-based methods and multivariate techniques. The impact of detector energy resolution will be discussed, highlighting the importance of precision instrumentation. Our results show that even in highly compressed and experimentally challenging scenarios, the clean environment and forward coverage of the Muon Collider can significantly enhance discovery potential, making it a compelling probe of dark sectors.

Advancing the Warm Calibration Unit for METIS on ELT: From Design Finalization to MAIT Phase

Date

2025-08-04

Speaker

Dr. Vipin Kumar

Venue

113/114, Thaltej Campus

Abstract

METIS, an advanced mid-infrared imager and spectrograph for the wavelength range 2.9-13.5 microns (astronomical L, M, and N-band), stands as one of the three science instruments at the Extremely Large Telescope (ELT). It will provide diffraction-limited imaging, coronagraphy, high-resolution integral field spectroscopy, and low and medium-resolution slit spectroscopy. Within the collaborative international METIS consortium, the University of Cologne is responsible for the design, manufacturing, and integration of the Warm Calibration Unit (WCU) of the instrument. The main role of WCU is to provide a stable and controllable reference signal to METIS that will allow troubleshooting and calibrating the response of METIS in various observing modes. In this talk, I will present the key requirements from METIS that drive the design of the WCU, followed by an overview of its optical and opto-mechanical design, and functional role within the instrument. The final part of the presentation will focus on the current status of the Manufacturing, Assembly, Integration, and Testing (MAIT) phase, including a brief discussion on the alignment verification plans for the offner relay optics of WCU.

Recent boulder falls on Planetary bodies: Insight into recent activities

Date

2025-08-01

Speaker

Dr. S Vijayan

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Rockfalls or boulder falls on Earth are very common and occur almost daily in certain parts of the world. In contrast, rockfalls on Mars are rare, and no rockfalls have been reported on the Moon in the last decade. This difference underscores the value of studying boulder falls on planetary bodies, as they provide important insights into geological processes. On planetary bodies like Mars and the Moon, millions of boulders/rocks are present on the surface, formed through the weathering of the crust, impact breccia’s, and other geological processes. These boulders vary in size, ranging from a few meters to several tens or even hundreds of meters. On the Moon, these boulders are particularly abundant. To date, using the latest high-resolution images from the Chandrayaan-2 Orbiter High-Resolution Camera (OHRC) and Lunar Reconnaissance Orbiter Narrow Angle Camera (LRO-NAC) there is no report of recent movement of even a single boulder over the past decade. This brings an intriguing question: do all the boulders on the Moon have reached equilibrium, or have there been movements in the last few decades to centuries, which is not been detected to date? How does the detection of movement of boulders help in understanding the recent activities? In this presentation, I will provide evidence for recent boulder falls and their hotspot regions on the Moon related to seismic activity/moonquakes, impact-generated surface shaking, and thermal weathering. Aside from very recent impacts, the primary activity observed on the Moon over the past few decades to centuries is the boulder falls. With the newly identified boulder falls, the Moon joins Earth and Mars, with records of recent boulder falls driven by multiple sources suggesting a sporadically active Moon. Such regions could be potential landing sites for future missions to understand the recent surface/subsurface activity on the Moon.

Broad-band study of the SMC pulsar RX J0032.9-7348 during its X-ray brightening in 2024

Date

2025-07-31

Speaker

Dr. Birendra Chhotaray

Venue

113/114, Thaltej Campus

Abstract

Accretion-powered X-ray pulsars (XRPs) are magnetized neutron stars that are part of X-ray binary (XRB) systems. The XRPs emit X-rays by accreting mass from their binary companion. These pulsars are characterized by intense magnetic fields, typically ranging from ~ 10^12-10^14 G, which direct the infalling material toward their magnetic poles, where most X-ray photons are generated. When the magnetic and spin axes are misaligned, the resulting emission is observed as pulsations from the neutron star. RX J0032.9-7348, an X-ray transient, was first detected by ROSAT in 1993; however, its properties are largely unknown. After years of inactivity, the source entered an X-ray bright phase in 2024. We observed it during this phase using NuSTAR and NICER. In this talk, I will present the timing and spectral properties of RX J0032.9-7348 during its 2024 outburst and discuss our ongoing and future work.

Genesis of uranium mineralization in the Singhbhum Shear Zone: constraints from geochemistry and geochronology of hydrothermal minerals

Date

2025-07-29

Speaker

Dr. Sarita Patel

Venue

Ground Floor Lecture Hall

Abstract

The genesis of uranium mineralization in the Singhbhum Shear Zone (SSZ), including the sources of the hydrothermal fluids has consistently remained a subject of debate. The present research deals with the Mohuldih and Bagjata uranium mine along the SSZ, India. The chemical and isotopic studies on the accessory minerals such as tourmaline, magnetite, fluorapatite, and monazite from the aforementioned mines were conducted to understand the mineralizing history in the Singhbhum Shear Zone. This discussion will focus on the distinct hydrothermal events and associated mineralization processes, as inferred from chemical compositions, isotopic signatures, and age data.

Census and Characterization of Hot and Variable Stars in Star Clusters

Date

2025-07-28

Speaker

Dr. Arvind K. Dattatrey

Venue

Online

Abstract

Hot and variable stellar populations in star clusters such as blue straggler stars (BSSs), blue lurkers, horizontal branch (HB) stars, and white dwarfs (WDs) offer critical insights into stellar evolution, binary interaction mechanisms and the dynamical evolution of stellar systems. In this talk, I will shed light on the characteristics and formation pathways of these non-canonical stars with a few case studies. I will discuss the detection of extremely low-mass white dwarfs (ELM WDs) as companions in BSS binary systems in Globular cluster NGC 362. In NGC 362, the radial distribution of BSSs exhibits strong central concentration, classifying the cluster as dynamically evolved and likely in a post-core-collapse phase. We also report the first identification of blue lurkers in a globular cluster. Two-component SED modeling reveals their companions to be low-mass and ELM WDs with short cooling ages (< 4 Myr), suggesting a recent formation event likely triggered by dynamical interactions during core collapse. In addition, we identify high-mass WDs in NGC 362, which may have originated via white dwarf–white dwarf mergers, a rare but theoretically predicted evolutionary channel in dense stellar environments. In the open cluster NGC 2420, four binary systems were identified, including two BSS binaries, one BSS–ELM WD system, and one HB–ELM WD system. These systems are consistent with formation via Case A/B mass-transfer pathways, indicative of stable binary evolution in low-density environments. Ongoing time-series photometric analysis has led to the identification of multiple variable stars, including pulsating and eclipsing systems, particularly among the BSS and HB populations. These variables provide independent diagnostics of internal stellar structure, angular momentum evolution, and rotational modulation. I will also discuss the ongoing spectroscopic analysis of BSS–RGB binary systems to further constrain the mass-transfer origin of BSSs, for understanding the role of binary evolution in shaping the hot stellar populations observed in star clusters.

Probing Parent Body Processing Through the Spectral Signatures of Insoluble Organic Matter in CM Chondrites

Date

2025-07-25

Speaker

Ms. Shreeya Natrajan

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

CM carbonaceous chondrites are time capsules preserving a complex history of aqueous alteration and thermal processing on their parent bodies. In this seminar, I will discuss how spectroscopic analysisof insoluble organic matter (IOM) from a wide suite of chondrites reveals temperatures (35–90°C) and duration of alteration. The variation in our estimates point towards multiple generations of organic matter, reflecting heterogeneity in parent body processes. Interestingly, some samples point to brief alteration events, while others hint at complex histories involving larger parent bodies or rubble-pile assemblies. These findings allow us to better understand the conditions under which primitive organic matter evolved in early solar system bodies.

Chemical compositions of the Ganga, Yamuna, Narmada and Tapi Rivers: An assessment of spatial and temporal variability

Date

2025-07-22

Speaker

Dr. Rakesh Kumar Tiwari

Venue

Ground Floor Lecture Hall

Abstract

Rivers are the major pathways which supplies metals from the continents to the oceans. The chemistry of these pathways plays a crucial role in riverine systems as they influence water quality and terrestrial biogeochemistry. Further, their riverine supply to ocean is crucial in regulating ocean productivity, influencing the oceanic biological pump, which modulates the atmospheric CO2 levels and global climatic variability. In this talk I will present a detailed investigation of the elemental chemistry in seasonally and spatially resolved samples from the Ganga, Yamuna, Narmada and Tapi rivers.

Lepton Flavor Universal New Physics in B-Decays?

Date

2025-07-22

Speaker

Dr. N Rajeev, PRL

Venue

Room no: 469 (Main Campus)

Abstract

"The flavor-changing neutral current (FCNC) semileptonic decays of B mesons offer a powerful avenue to indirectly probe New Physics (NP) beyond the Standard Model (SM). I will review the current status of the so-called B anomalies. While lepton flavor universality (LFU) ratios such as RK and RK∗ are in good agreement with SM predictions, notable deviations persist in individual branching fractions—for instance, B(B+ → K+μ+μ−) and B(B+ →K+e+e−), both of which deviate at the 4 − 5σ level. Additionally, the angular observable P'5 in B → K∗μ+μ− exhibits a 3.3σ deviation, and a 3.6σ discrepancy is reported in B(Bs → φμ+μ−). Although the recent measurement of Rφ is consistent with the SM, the individual branching fractions remain at odds with expectations. These persistent anomalies hint at NP contributions in both muon and electron sectors. Given that experimental bounds on b → see transitions are still relatively loose, NP might also manifest in the first-generation lepton sector. Motivated by these observations, we perform a global analysis of dimension-6 SMEFT operators, considering the possibility of NP contributions not only in b → sμμ transitions but also in b → see transitions."

Characterizing AGN and dual AGN duty cycles in SMUGGLE isolated merger simulations

Date

2025-07-17

Speaker

Mr. Jay Motka

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Observational data show strong correlations between the mass of supermassive black holes and the properties of their host galaxies, leading to the idea of SMBH-galaxy co-evolution. Galaxy mergers are interesting events as gravitational torques during mergers drive gas towards galactic nuclei, which can enhance AGN activities. This leads one to question: to what extent do mergers enhance AGN activities compared to isolated galaxies, and how does this impact the galactic environment? In this talk, I shall elaborate on our efforts to answer this question by introducing Stars and MUltiphase Gas GaLaxiEs (SMUGGLE), a framework based on the hydrodynamic code AREPO with a multiphase interstellar medium. I shall talk about the limitations of traditional simulations, improvements in SMUGGLE, and other simulation specifications. Our efforts in characterizing the duty cycles of AGNs and dual AGNs during mergers have shown that Multiphase ISM in SMUGGLE yields highly variable accretion rates with short duty cycles. In mergers, the mean active phase timescales are in the order of 0.1 Myr to 1 Myr, and dual AGNs seem to be active for 10-20 per cent of the simulation time before the black holes merge. Differences in black hole masses, galaxy morphologies, and wind speeds do show a significant impact on AGN and dual AGN activities. I shall conclude with a summary of current results, as well as ongoing and future work.

On the T-linear resistivity of cuprates: theory

Date

2025-07-14

Speaker

Prof. Navinder Singh, PRL

Venue

Room no: 469 (Main Campus)

Abstract

"By partitioning the electronic system of the optimally doped cuprates in two electronic components: (1) mobile electrons on oxygen sub-lattice; (2) localized spins on copper sub-lattice, and considering the scattering of mobile electrons (on oxygen sub-lattice) via generation of paramagnons in the localized sub-system (copper spins), we ask what should be the electron-paramagnon coupling function Mq so that T-linear resistivity results both in the low temperature limit (kBT << ~ωqcut) and in the opposite high temperature limit (qcut is a characteristic paramagnon cut-off wave vector). This ’reverse engineering approach’ leads to |Mq| scaling inversely with wave vector. We comment how can such exotic coupling emerge in 2D systems where short range magnetic fluctuations resides. In other words, the role of quantum criticality is found to be crucial. And the low temperature T-linear behaviour of resistivity demands that the magnetic correlation length scales as ξ(T) scales as 1/T which seems to be a reasonable assumption in the quantum critical regime of cuprates (that is, near optimal doping where T-linear resistivity is observed). "

The Role of Deformed Craters in Understanding Fault Kinematics and Geometries

Date

2025-07-11

Speaker

Dr. Kimi Khungree Basumatary

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Understanding subsurface faults is inherently challenging, especially on planetary bodies where direct field observations are not possible. Numerous studies have relied on high-resolution imaging, topographic data, and numerical simulations to analyze surface features such as wrinkle ridges and lobate scarps, which are expressions of underlying thrust faults on the Moon, Mars, and Mercury. These surface morphologies reflect a range of fault geometries, including buckle folds, fault-bend folds, and backthrusts, though no consensus exists on their exact subsurface structures. Fault-controlled deformed craters—impact craters modified by fault movement—offer an alternative means of inferring fault orientation, displacement, and dip. Prior studies have used crater wall exposures and rim circularity to estimate fault parameters, but these approaches face limitations when traces are confined to crater walls or when craters are circular. To address this, we developed a method that applies to both crater walls and floors and accommodates various crater shapes. In my talk, I will present the methodology and results in detail.

Sediment Connectivity in India’s Large River Basins under Climate and Human-Induced Stress

Date

2025-07-08

Speaker

Dr. Abhishek Dixit

Venue

Ground Floor lecture hall

Abstract

Currently, large river systems are under increasing stress due to climate-driven extreme events, floods, human interventions, and concerns over delta sustainability. These systems span diverse geomorphological, climatic, and lithological domains, each contributing uniquely to the basin’s sediment dispersal processes. These domains are activated or suppressed in response to external forcings such as climate extremes and human activities. In this talk, I will discuss these factors in the context of three major Indian river basins: the Brahmaputra, the Ganga, and the Godavari. I will show how the alluvial plains, particularly in the Ganga and Brahmaputra basins, may be highly sensitive to seasonal-scale fluctuations, which in turn influence sediment budgets and provenance signals. At the same time, climate-driven extreme events are leaving far-reaching and persistent imprints, with sediment signals traceable as far downstream as the Bengal delta. I will also explore how human interventions, particularly dams, have disrupted sediment connectivity within these river systems. Almost all of the observed reduction in sediment load can be attributed to reservoir storage, placing parts of the delta at risk of sinking. In conclusion, while climate-driven forces are significant, human-induced interventions are leaving equally, if not more, profound imprints on the sediment dynamics of India’s large river systems. A carefully integrated methodological approach is essential to effectively address these complex interactions.

Mineralogical Characterization of Mare Australe: A Unique Region on the Moon

Date

2025-07-04

Speaker

Dr. Neha Panwar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Mare Australe (47.77°S, 91.99°E) is a volcanic province ~1000 km in diameter at the eastern nearside and farside boundary of the Moon. It consists of 248 mapped basaltic patches arranged in a more-or-less circular pattern. Initially classified as a “distinct” basin, it was later considered a “no topographic basin” due to a lack of identifiable topographic features. The results from the GRAIL mission, did not confirm the presence of a basin coinciding with the previously proposed one. Instead, GRAIL suggested the presence of a ~880 km diameter impact structure northwards named the Australe North Basin centered at 35.5°S, 96°E. In the earlier study geological evidences were provided to further establish the presence of the Australe North Basin. Volcanic activity at Lacus Solitudinis and Bowditch Crater, once thought to be isolated, is now linked to Australe North Basin. Based on the re-defined basin boundaries in the region a significant part of Mare Australe’s basalts lie outside the boundaries of Australe North. These basaltic units of Mare Australe remain largely uncharacterized. In this seminar, I will present a detailed investigation into the mineralogical diversity of the Mare Australe region. This study aims to shed light on the nature and origin of the distinctive style of volcanism in the region, highlighting the unique geological setting of Mare Australe and its implications for lunar volcanic evolution.

Atmosphere Characterization of the Hot-Jupiter Exoplanets

Date

2025-07-03

Speaker

Dr. Soumya Sengupta

Venue

ONLINE

Abstract

Hot Jupiters, tidally locked to their host stars, exhibit extreme day–night temperature contrasts that drive vigorous atmospheric circulation. In my recent work, I analytically and numerically quantified how this heat redistribution shapes their temperature–pressure (T–P) profiles and dayside emission spectra. Using discrete space theory radiative transfer simulations, I demonstrated that reduced heat redistribution leads to hotter daysides, stronger thermal inversions, and higher emission fluxes. Application to exoplanet XO-1b revealed near-complete heat redistribution, resolving key degeneracies in its atmospheric characterization. Beyond circulation, my research also addresses two crucial aspects: • Radius Inflation: Ionized atmospheric flows coupled with magnetic fields generate Ohmic dissipation within the radiative and convective zones. MESA evolutionary simulations, parameterized by atmospheric flow velocities, successfully reproduce the observed inflated radii of hot Jupiters through this internal heating mechanism. • Spectral Separation: I have generalized Chandrasekhar’s diffuse reflection theory to unify thermal emission and scattering, allowing precise separation of planetary spectra from stellar contamination in ultra-hot Jupiters. In future work, I plan to integrate equilibrium and non-equilibrium chemistry into circulation models to better capture day–night variations in chemical abundances to study the effect of atmospheric heat redistribution on the atmospheric chemistry and finally its imprints on the emission spectra. Additionally, I aim to extend these frameworks to lower-mass, potentially habitable tidally locked terrestrial planets to inform climate and habitability studies. I also plan to develop improved radiative transfer tools that can simultaneously handle complex emission, scattering, and chemical processes, providing stronger predictive power for upcoming JWST and ARIEL observations.

Palaeoceanographic implications of single planktonic foraminiferal isotopic analysis

Date

2025-07-01

Speaker

Dr. Sanchita Banerjee

Venue

GFL

Abstract

Planktonic foraminifera have the ability to archive geochemical signatures of seasonal scale due to their short life spans. We utilized stable isotopes in individual foraminiferal tests to reconstruct sur-face ocean conditions and climate fluctuations over the past few thousand years in the Northern In-dian Ocean. We developed a state-of-the-art methodology for measuring the clumped isotope com-position (Δ47) of individual foraminiferal tests, marking the first such attempt. This approach holds the potential to reconstruct past ocean temperatures, offering unprecedented insights into short-term climate dynamics. We also analyzed δ13C and δ18O isotopic ratios in single foraminifera to resolve vertical habitat signals and understand the variation in mixed layer depths. These multi-isotope da-tasets allow us to better understand the physical and chemical structure of the upper ocean and its response to past climate change. In this talk, I will present preliminary results from this novel single-foram clumped and conventional isotope analysis, and discuss their implications..

Towards understanding lunar hydration using Chandrayaan-1 and Chandrayaan-2 NIR spectrometers

Date

2025-06-27

Speaker

Dr Megha Bhatt

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Moon Mineralogy Mapper (M3) onboard Chandrayaan-1 has been extensively utilized to map the global surface composition and detect OH/H2O on the lunar surface. It was the first instrument to systematically detect and map the 3-µm absorption feature associated with hydration, using observations acquired at different times of the lunar day. However, the compositional dependencies and temporal variability of this feature, especially in the polar regions, remain poorly understood. Moreover, M3’s limited spectral coverage—extending only up to 3.0 µm—restricted its ability to fully characterize the hydration feature and to distinguish between OH and H2O. The Imaging InfraRed Spectrometer (IIRS) onboard Chandrayaan-2 addresses this limitation by extending the spectral range to 5.0 µm, thus enabling discrimination between OH and H2O signatures. However, IIRS data also come with certain limitations that must be carefully understood before it can be reliably applied at the global scale. In this talk, I will present our i ndependent methodology for processing IIRS data in parallel with M3, aimed at achieving cross-calibration and a robust comparison of hydration features. We have selected multiple overlapping IIRS observations, including well-characterized landing sites, and categorized them based on lunar local time to study diurnal variations. After applying dark current subtraction, radiometric correction, and thermal emission modeling, the IIRS spectra were geometrically aligned with M3 and corrected for topographic and photometric effects. I will share our preliminary results, insights gained from the IIRS data processing workflow, and our outlook for integrating IIRS and M3 data in a comprehensive global-scale analysis.

Factors affecting gas-particle partitioning of the NHx system

Date

2025-06-24

Speaker

Ms. Chandrima Shaw

Venue

Ground Floor Lecture Hall

Abstract

Ammonia (NH3) and its particulate form ammonium (NH4⁺) together form the reactive nitrogen system NHx, which plays a key role in air quality, particulate matter formation, and nitrogen deposition. The gas-particle partitioning of NHx is influenced by several factors like meteorology (temperature and relative humidity) and atmospheric chemistry (pH and aerosol liquid water content (ALWC)) with a complex interplay between them. While low temperature and high RH promote the partitioning towards the particulate phase, higher temperature shift it back to the gas phase. Aerosol pH and ALWC further control this balance, by governing the effect of this partitioning on PM load. While pH and ALWC influence the partitioning of gases into their particulate counterparts, this partitioning in turn affects the aerosol pH, creating a two-way interaction between chemical composition and aerosol thermodynamics. Given the multifaceted importance of the NHx system, it is essential to understand how meteorology and aerosol chemistry together, shape the gas-particle partitioning. This seminar aims to provide a deeper insight into the gas-particle partitioning dynamics of NH3 and NH4+, focusing on the role of temperature, RH, pH, and ALWC under different conditions.

Cosmogenic Nuclides in Meteorites: Constraining Cosmic Ray Exposure and Terrestrial Ages

Date

2025-06-24

Speaker

Dr. Satvika Jaiswal

Venue

ONLINE

Abstract

Cosmogenic nuclides, produced by interactions between cosmic rays and meteoritic matter, are powerful tools for determining the cosmic ray exposure (CRE) ages and terrestrial residence times of meteorites. This talk will highlight the combined approach using Accelerator Mass Spectrometry (AMS) along with Noble Gas Mass Spectrometry (NGMS) to estimate both CRE and terrestrial ages. The talk will discuss how radionuclides such as ¹⁰Be, together with stable noble gases like ²¹Ne, help reconstruct the exposure history, shielding conditions, and delivery mechanisms of meteorites. These methods play a key role in understanding the journey of meteoroids from space to Earth and contribute toward developing robust AMS measurement protocols at PRL.

"Modeling Superconductivity, Magnetism, and Quantum Phenomena in Complex Materials"

Date

2025-06-24

Speaker

Dr. Smritijit Sen, University of Florence

Venue

Online--- https://imeet.vconsol.com/join/4438320547?be_auth=MjE2MTAy

Abstract

We present a comprehensive exploration of quantum materials through state-of-the-art theoretical and computational techniques. Focusing on superconductivity, we delve into intra- and interband pairing mechanisms via Eliashberg formalism and model Hamiltonians, examining how pressure and doping drive Lifshitz transitions. The impact of magnetic impurities on superconducting states is analyzed using density functional theory (DFT) and Green’s function methods with potential applications in developing robust qubit platforms for quantum computing. We further investigate electronic structures through band dispersion, Fermi surfaces, and density of states to interpret experimental probes such as ARPES and IETS. We also highlight structure-property correlations under thermal perturbations, advanced crystal structure prediction using evolutionary algorithms like USPEX, and ongoing work on the optical and photocatalytic properties of mixed anionic systems, including thio-apatites with potential for solar-driven hydrogen production.

Concentrations of Hydrogenated, nitrogenated, & protonated sulfuric acid ions due to GCR (Galactic Cosmic Rays) impact ionization in lower atmosphere of Venus.

Date

2025-06-20

Speaker

Ms Aastha Kumayu

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Solar radiation interacting with the Venusian atmosphere produces two prominent ionization layers: V2 (~140 km) and V1 (~125 km). However, due to the high atmospheric density, only Galactic Cosmic Rays (GCRs) can penetrate into the deeper layers of the Venusian atmosphere. As cosmic ray air showers propagate through the Venusian atmosphere, they develop extensively until reaching a maximum, typically located between 60 and 70 km, below this altitude, the flux of secondary particles steadily declines due to their insufficient energy to sustain ionization. Previous studies have theorized the ion-pair production rates in this region with negligible focus on ionic species responsible. This presentation will begin with a general overview of the Venusian atmosphere, followed by a concise explanation of the methodology and chemical model we have used to compute electron densities and ion concentrations for 74 ion species in this region. The talk will conclude with a discussion on of some of the dominant ions identified in the lower region, for example hydrated hydronium ions and hydrated ions of NO2-, CO3-.

Observing Solar Flares with SUIT: A New Window into the Near-Ultraviolet Sun

Date

2025-06-19

Speaker

Soumya Roy

Venue

Online

Abstract

Solar flares are among the most energetic phenomena in the solar system, driving rapid restructuring of magnetic fields and heating across the solar atmosphere. While much progress has been made in understanding flares through observations in X-rays and extreme ultraviolet (EUV), the near-ultraviolet (NUV) range remains relatively unexplored—despite its sensitivity to key layers like the lower chromosphere and upper photosphere, where much of the flare energy is deposited. The Solar Ultraviolet Imaging Telescope (SUIT), onboard India’s Aditya-L1 mission, is the first instrument to provide full-disk solar imaging in multiple NUV passbands, opening a new window into this critical regime. In this talk, I will first outline the current state of flare research and highlight the observational and diagnostic gaps that exist in the NUV. I will then introduce SUIT’s science objectives in the context of these challenges. As part of my PhD, I contributed to the initial design of SUIT. I will also present our first results from SUIT, and discuss how these data can inform models of chromospheric heating and flare energy transport. This work sets the stage for SUIT’s long-term contribution to high-cadence, multi-height solar flare studies.

Probing collective response in the quantum system using Raman scattering

Date

2025-06-17

Speaker

Dr. Surajit Sarkar, CEA Grenoble, France

Venue

Online---https://imeet.vconsol.com/join/8046909791?be_auth=NDgyMTQy

Abstract

"Raman scattering is an inelastic light scattering process in which energy is transferred from incident light to the system, and the strongest signal often appears in the absorption spectrum from the collective mode present in the quantum system. In the first part of the talk, I will present a novel effect arising from inversion symmetry broken spin-orbit coupling (SOC) on charge collective modes, plasmons, and how this could be studied using electronic Raman scattering. I will discuss that isolated plasmons could be strongly prominent in resonant eRS in the presence of spin momentum locking SOC in BiTeI, which were invisible previously due to standard $q^2$ suppression, where $q$ is the momentum transferred by the light. The last part of the talk is on Raman response in superconductors. Here, I will discuss the electronic Raman response (eRS) of multiband SC in both A1g and B1g channels across the time reversal symmetry broken transition and the potential possibility of Leggett and Bardassis-Schreiffer modes in the observed spectrum, depending on the nature of the ground state. We will also see from our results that eRS could be used as a probe to detect spontaneously broken time reversal symmetry of superconductors such as s+is and s+id states."

Multi-mode study of exotic stellar populations in dense stellar systems

Date

2025-06-12

Speaker

Gaurav Singh

Venue

Online

Abstract

I will present a systematic study of exotic stellar populations-Blue Stragglers (BSS) and Extreme Horizontal Branch (EHB) stars-in dense environments of the Milky Way and satellite dwarf galaxies. Despite decades of research, their formation channels, binary companions, and chemical evolution remains poorly understood due to their diverse properties across different environments. These UV-bright objects have now become accessible through new facilities like AstroSat/UVIT and public catalogs, revealing previously unknown extreme systems that challenge existing stellar models. To resolve these puzzles, I propose a coordinated multi-wavelength campaign utilizing high and medium-resolution spectroscopy (ground-based optical/infrared observatories), UV diagnostics (HST, UVIT/AstroSat, Swift/UVOT), and astrometry (Gaia and HST). This approach will uncover binary interactions, atmospheric anomalies, and evolutionary pathways-providing critical insights into stellar rejuvenation mechanisms and revealing new characteristics of these stellar populations.

Farside Volcanism on the Moon: A Remote Sensing Perspective

Date

2025-06-06

Speaker

Ms Tvisha R. Kapadia

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Volcanism on the Moon is primarily manifested in the form of mare basalts, which cover ⁓17% of its surface. Mare basalts exhibit significant compositional diversity and are mainly concentrated within and adjacent to the large circular impact structures, and have a total volume estimated at ~107 km3. Interestingly, the distribution of mare basalts is highly asymmetric, whereby the nearside hosts extensive basaltic emplacements and the farside exhibits remarkably fewer mare basalts. In my talk, I will be providing a detailed account of how the understanding of this fundamental dichotomy has evolved from the first glimpse of the farside by Luna 3 in 1959 to present-day (with missions like Clementine, Lunar Prospector, LRO, Chandrayaan, Kaguya, GRAIL, Chang’e). Despite these advances, key questions remain unanswered on the nearside-farside dichotomy in volcanism. I will discuss the existing gaps in the knowledge and the objectives of my thesis. The talk will conclude with preliminary results based on morphological and chronological studies of the Freundlich-Sharonov Basin, one of my study areas on the farside of the Moon that exhibits evidence of mare emplacement.

Development of Readout Electronics for Plastic Scintillators Coupled with a Photomultiplier Tubes (PMTs) for a Hard X-ray Compton Polarimeter

Date

2025-05-23

Speaker

Mr. Deepak Kumar Painkra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Photons preferentially undergo Compton scatter perpendicular to the plane of polarization, a property that enables the measurement of linear polarization in hard X-rays. A Compton polarimeter employs a low-Z scatterer to maximize the probability of Compton scattering. This central scatterer is surrounded by a high-Z absorber, which detects the azimuthal distribution of scattered photons. In such a configuration, the lowest photon energy at which polarization can be effectively measured is determined by the lower energy detection efficiency of the scatterer. The efficiency is, in turn, limited by the noise performance of the readout electronics. In this seminar, I will present an overview of the design considerations of the Hard X-ray Compton Polarimeter, with a focus on the development of readout electronics for the scatterer, a plastic scintillator coupled with a PMT. I will also discuss the experiment setup to characterize its detection efficiency at lower energies, aiming to improve the polarimeter sensitivity.

Neutrinoless double beta decay in an realistic SU(5) Model

Date

2025-05-20

Speaker

Debashis Pachhar, PRL

Venue

Room no: 469 (Main Campus)

Abstract

Baryon number (B) and lepton number (L) are accidental global symmetries of the Standard Model (SM). Any observed violation of these quantum numbers would provide unambiguous evidence for physics beyond the SM. Grand Unified Theories (GUTs) offer a well-motivated framework to study such violations. In this seminar, I will discuss the role of heavy scalar fields in mediating lepton number violation via neutrinoless double beta decay (0νββ) within the SU(5) framework. While the minimal SU(5) setup predicts extremely suppressed contributions to 0νββ due to the heavy scalar masses – as a consequence of the proton decay bound, we will show that this limitation can be circumvented by extending the model. Specifically, the introduction of a discrete ℤ3​ symmetry and the inclusion of an additional 15-dimensional scalar representation allow for dominant contributions to the decay process. Such an extension not only remains consistent in yielding realistic fermion mass spectra but also leads to experimentally testable predictions in upcoming ton-scale 0νββ searches.

The Secret Lives of Galaxies: From Dusty Starbursts to Buried Black Holes

Date

2025-05-20

Speaker

Dipanjan Mitra

Venue

Online:https://imeet.vconsol.com/join/9277507210?be_auth=NDc5OTIx

Abstract

Abstract - Galaxies are the building blocks of the Universe, and some of the most massive and mysterious ones formed when the Universe was just a few billion years old. Many of these early galaxies were rich in dust and forming stars at high rates, yet hidden from view in visible light. These dusty star-forming galaxies (DSFGs) played a key role in building today’s giant elliptical galaxies, and understanding them is essential to piecing together the story of galaxy formation. In my recent work, I used data from space and ground-based telescopes (JWST, Euclid, Herschel, and LSST) to show how we can trace the stars, dust, and AGN activity in these galaxies across cosmic time, and developed physical models. In this talk, I shall demonstrated that by combining multi-wavelength data (from ultraviolet to far-infrared) we can get a complete picture of how galaxies evolve, even when they are deeply buried in dust. I shall also discuss the role deep radio surveys in unveiling obscured active galactic nuclei (AGN) at high redshifts.

Dynamics of Dissolved Organic Matter in Regulated River Systems

Date

2025-05-20

Speaker

Ms. Ganika Kushwah

Venue

Ground Floor Lecture hall

Abstract

The dynamics of dissolved organic matter has always been complex because of their largely unexplored nature. Freshwater systems such as rivers are vital components of the global biogeochemical system as they act as conduits for transporting large quantities of dissolved organic matter (DOM) from terrestrial landscapes to the ocean. However, their role in DOM dynamics still remains underexplored, specifically from a biogeochemical perspective. Moreover, the anthropogenic alteration to it’s flow regime has put a limit to its transport mechanism-reducing its export. In ths seminar, a basic review of a DOM in riverine system along with results obtained from regulated river systems in western India will be presented

Investigation of Organic Matter in Differentiated Meteorites: Unveiling Indigenous Origins and Impact Dynamics

Date

2025-05-16

Speaker

Ms. Neha

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The nature of organic matter in meteorites provides insights into early solar system chemistry and the evolutionary histories of their parent bodies, reflecting processes from nucleosynthesis and dust formation to planetesimal and planetary development over the last 4.5 billion years. This talk provides an overview of the first detailed investigation into the nature and origin of insoluble organic matter (IOM) in aubrites, a rare class of differentiated meteorites. I will present a multitechnique analysis of IOM in aubrites and enstatite chondrites, aimed at understanding the extent of organic distribution within the protoplanetary disk and the physicochemical processes that offer essential clues to their parent body evolution. In this seminar, I will discuss the spectroscopic analyses of the IOM in aubrites compared with chondrite IOM to understand the structural and molecular heterogeneity in different meteorite classes. Further I will be discussing the microscopic studies of these organics highlighting the different carbon morphologies present in aubrites. The results offer new insights into the complex evolutionary history of aubrite parent bodies and contribute to a broader understanding of organic matter preservation in differentiated planetary materials.

Can CO2 outgassing explain the Lomagundi carbon isotope excursion?

Date

2025-05-15

Speaker

Mr. Janaarthanan P A

Venue

Ground Floor Lecture hall

Abstract

The Lomagundi-Jatuli excursion event (2.3-2.0 Ga) is one of grandest carbonate isotopic excursion events in the geological history, that is said to mark a global perturbation in carbon cycle. The canonical explanation given for this excursion attributes it to be the resultant of enhanced organic carbon burial. But, the lack of geological evidence for an enhanced organic matter accumulation prior to or synchronous with the excursion, leaves this event an unanswered puzzle. Furthermore, recent insights from sedimentological facies-based studies challenges the presumed global extent of this excursion. In this discussion we will evaluate the canonical organic burial mechanism and explore the possibility of CO2 outgassing as a potential driver responsible for this excursion.

N-Body Integration Model for Dust Dynamics and Flux Estimation in Inner Solar System

Date

2025-05-14

Speaker

Ms. Aanchal Sahu

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Interplanetary Dust Particles (IDPs), originating from the Asteroid Belt, Kuiper Belt, Oort Cloud, and comets, are fundamental to many Solar System phenomena such as Zodiacal Light and meteor showers. As these particles spiral inward toward the Sun, their orbits are altered by a complex interplay of gravitational and non-gravitational forces, leading to gradual perturbations in their orbital elements. The mathematical formulation of the force models, orbital perturbation equations, and their impact on dust evolution will be discussed. We utilize and analyse the N-body problem using Everhart’s RA15 version of the RADAU integrator, which is particularly well-suited for handling stiff orbital equations. I will be presenting results highlighting how Mean Motion Resonances (MMRs) facilitate the capture and long-term trapping of dust particles near planets which can alter dust trajectories. Additionally, methodologies for statistical estimation of dust flux on planetary surfaces by analysing the position of dust particles over time during their close encounters with planets will be discussed. The velocity distribution of impacting particles will also be examined to provide a more complete picture of dust-planet interactions.

Electron-phonon coupling induced topological phase transitions in an α-T3 quantum spin Hall insulator

Date

2025-05-13

Speaker

Dr. Kuntal Bhattacharyya, IIT Guwahati

Venue

Room no: 469 (Main Campus)

Abstract

We study the phenomenon of topological phase transitions induced by electron-phonon (e-ph) coupling in an α-T3 quantum spin Hall insulator that presents smooth tunability between graphene (α = 0) and dice (α = 1) lattice. Upon deriving an effective electronic model under suitable transformations, we come across different regimes of α, which host distinct topological transitions solely mediated through e-ph coupling, manifesting robust support from the bulk gap closing and the relative changes in the topological invariant together with the edge state features. The critical e-ph strengths of these transitions strongly depend on α. We also observe the evidence of an emergent second-order topological insulator (SOTI) phase in our system, which is characterized by the existence of corner modes and its topological marker. Interestingly, these corner modes are wiped out beyond a critical e-ph coupling (albeit different for different α), referring to a SOTI-trivial phase transition induced by the e-ph coupling.

Fate of Environmental Microplastics

Date

2025-05-13

Speaker

Prof. Neeraj Rastogi

Venue

Ground Floor Lecture hall

Abstract

Microplastics (MPs) are omnipresent on the Earth, found everywhere from Mount Everest to the Mariana Trench, and from fishes to human body. MPs are known to affect human and environmental health directly/indirectly. However, research on MPs is in initial stage only with major focus on 'MPs in water bodies'. This talk will provide a brief overview on the MP research done in different environmental systems and future perspectives.

Understanding evolution of cometary volatiles

Date

2025-05-09

Speaker

Mr Akshat Rawat

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Understanding the evolution of volatiles on the surfaces and subsurfaces of comets is crucial to studying their thermal, chemical, and structural history. This talk will provide an overview of the key physical processes driving volatile sublimation on comets, including heat conduction, sublimation, and gas diffusion through porous subsurface material. I will then discuss previous models of cometary nuclei and comae, highlighting their limitations—such as neglecting long-term thermal evolution, relying on simplified geometries (spherical or quasi-3D), underutilizing recent spacecraft data, and lacking integration between nucleus and coma evolution. Addressing these gaps, my research focuses on developing a model that comprehensively links the cometary surface and subsurface with the cometary atmosphere to study volatile evolution. This includes implementing coupled thermophysical and sublimation modelling across realistic comet geometries to interpret cometary activity better and simulate volatile loss over time—particularly at larger heliocentric distances (>3 AU), where CO and CO₂ dominate over H₂O as primary drivers of activity.

Atmospheric evaporation from exoplanets

Date

2025-05-07

Speaker

Dr. Gopal Hazra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The habitability of any planet is decided by a complex evolution of its interior and atmosphere. Recently in many observations, it has been found that close-in exoplanets are going through significant atmospheric evaporation, which could affect the overall evolution of the exoplanet atmosphere. This atmospheric evaporation from exoplanets is very much dependent on the plasma and radiation environment of their parent stars (e.g., stellar radiation, stellar wind, stellar flares, and Coronal Mass Ejections (CMEs). In this talk, I will explain different physical processes (e.g., Jeans escape, hydrodynamic escape) by which an exoplanet can lose its atmosphere. One major process that leads to significant loss of exoplanetary atmosphere is the stellar radiation-driven atmospheric outflow. Once planetary outflow is initiated from the planet by stellar radiation, it further interacts with the stellar wind shaping up the exoplanetary atmosphere (sometimes producing a comet-like structure) and its atmospheric mass-loss rate. Moreover, flares and coronal mass ejections (CMEs) from the star will also have a great impact on planetary evaporation and mass loss. I will present our newly developed 3D radiation magnetohydrodynamics model where we have implemented a self-consistent radiative transfer of incident stellar radiation to simulate planetary outflow and its interaction with the stellar wind, CMEs, and flares. I will show that radiation-driven planetary outflow alone can not explain the observed transit signatures & corresponding mass-loss rate, but the interaction with the stellar wind/coronal mass ejections can explain the observed mass-loss rate and transit for many exoplanets. I will also discuss briefly the effect of stellar and planetary magnetic fields on the atmospheric mass-loss rate and corresponding observational signatures.

Study of Neutrino Oscillation with non unitarity

Date

2025-05-06

Speaker

Pathan Tamanna, National Institute of Technology Surat

Venue

Room no: 469 (Main Campus)

Abstract

In this talk we will present the neutrino oscillation probabilities in presence of a non unitary mixing matrix . We will show the oscillation probabilities both in vacuum and including matter effects, Using the expressions of probabilities derived, we will show at which energies and baselines the signature of non unitary will be significantly different from standard scenarios.

Corals as geochemical proxy for N:P ratio: Insight from modern corals

Date

2025-05-06

Speaker

Dr. Abul Quasim

Venue

Ground Floor Lecture hall

Abstract

Globally, phytoplankton typically maintain the Carbon:Nitrogen:Phosphorus (C:N:P) ratios close to the Redfield ratio (~106:16:1), which reflects the balance of nutrients required for their growth. Therefore, these ratios serve as a baseline for assessing nutrient availability or limitation and carbon export efficiency. Understanding the future shifts in oceanic C:N:P ratios is essentially required for predicting the future trends of the biological pumps under the global climate change scenario. Recent studies reveal that the C:N:P ratios in the global ocean vary regionally, and their future projections are highly uncertain. Understanding the past variability in the C:N:P ratios could improve predictions. However, no geochemical proxy for C:N:P ratios at present. In this context, we analyzed C:N:P stoichiometry as well as d13C and d15N in different layers of modern corals (including coral-mounted algal biofilms) and surrounding seawaters and particulate organic matter collected from the Gulf of Kutch. In this talk, I will share insights into C:N:P ratios in the global ocean, and key findings highlight the efficiency of corals in capturing marine nutrient signatures and the biogeochemical processes shaping elemental and isotopic patterns.

Decoding Aqueous Alteration on Mars: Insights from Water/Rock (WR) ratios in Open and Closed Systems

Date

2025-05-02

Speaker

Mr Aditya Das

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

In this talk, I will discuss how water/rock (WR) ratios under open and closed system conditions shape secondary mineral formation on Mars. For this, I shall be analyzing the secondary minerals on both Martian meteorites and terrestrial analogues (Deccan basalts from the Kutch area), which will help in understanding the geochemical conditions responsible for such alteration processes that will offer fresh insights into past climates and alteration histories on Mars.

Time-Dependent Modeling of Extreme Gamma-Ray Flares of Blazars

Date

2025-05-01

Speaker

Anton Dmitriev

Venue

Online

Abstract

Blazar flares offer a unique window into the extreme physics of relativistic outflows, including particle acceleration and the origin of multi-wavelength (MWL) emission. A key approach to studying these processes is physical modeling of varying blazar jet emission. Many numerical codes employ a kinetic framework to track particle spectrum evolution under various physical effects. We have developed EMBLEM (Evolutionary Modeling of BLob EMission), a versatile radiative code based on time-dependent particle (re-)acceleration, escape, radiative cooling, and adiabatic expansion. This code allows us to self-consistently connect low state and flaring emission. Based on a leptonic framework, the code incorporates synchrotron self-Compton (SSC) and external Compton (EC) scenarios. We showcase its application to (1) modeling extreme gamma-ray flares in blazars such as Mrk 421 and 3C 279, and (2) searching for internal gamma-ray opacity signatures in high-redshift blazars.

Neutrinos in Cosmology

Date

2025-05-01

Speaker

Sanjit Kumar, NIT Jamshedpur

Venue

Room no: 469 (Main Campus)

Abstract

In this talk, we will begin by introducing the basics of neutrinos and their significant role in cosmology. We will discuss the thermodynamics of the early universe and examine the Boltzmann equation and the process of neutrino decoupling. Moving forward, we will explore the nature of dark matter and investigate whether neutrinos could serve as viable dark matter candidates. We will then review cosmological constraints on neutrino masses. Finally, we will discuss the possibility of sterile neutrinos as dark matter. Throughout the talk, we aim to highlight how neutrinos influence key processes in the early universe and their relevance in modern cosmology.

Magnetic Accretion Signatures in High-Field Cataclysmic Variables

Date

2025-04-29

Speaker

Akash Sundriyal

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Cataclysmic Variables (CVs) are examples of semi-detached binary star systems characterized by the flow of stellar material from the companion star to the primary (white dwarf). If the primary possesses a significant magnetic field, the accretion dynamics can be drastically altered. In particular, polar magnetic CVs, characterized by their strong magnetic fields are often marked by the lack of an accretion disk and also exhibit unique observational signatures, such as highly polarized radiation, synchronous rotation, etc. In this talk, I will discuss the properties of these high field systems and the interaction between the magnetic field and the accretion flow which can lead to complex phenomena, including emission of X-rays and cyclotron radiation. I will then explain some methods used to probe the magnetic field in such systems. I will also discuss the identification of potential high field systems from a sample of CV candidates from the 5th data release of the LAMOST (Large Sky Area Multi-Object Fiber Spectroscopic Telescope) spectroscopic survey. I will conclude my talk by presenting an estimate for the magnetic field in LAMOST J003553.36+433341.4 from its LAMOST spectrum.

Investigating the Impact of Hydrogen on Lunar Neutron Leakage Flux

Date

2025-04-25

Speaker

Ms. Shipra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Moon's lack of a magnetic field and atmosphere exposes its surface to ionizing radiation, including the solar wind, solar energetic particles (SEPs), and galactic cosmic rays (GCRs). High-energy GCRs interact with the lunar surface, generating fast neutrons through nuclear reactions. These fast neutrons are moderated by collisions with the nuclei in the lunar soil and can leak out, acting as messengers of the soil’s composition. Studying the neutron leakage spectrum can reveal important information about the abundance of near-surface hydrogen. In this seminar, I will discuss the production and moderation processes of neutrons within the lunar surface, followed by an explanation of how the leakage neutron flux depends on hydrogen and other elements.

Verification of the Dynamically New Comets: Results from the N-body Simulation

Date

2025-04-24

Speaker

Goldy Ahuja

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Comets are the preserved minor bodies which holds the primitive information about the early solar system. These bodies come into the inner solar system from two reservoirs, i.e., Kuiper Belt and Oort Cloud. Kuiper Belt is the source of Short-Period, low-inclination comets (SPCs) whereas Oort Cloud is the source of Long-Period Comets (LPCs) having isotropic inclination. Dynamically New Comets (DNC) are a long-period comets, with a semi-major axis > 10000 AU, entering the inner Solar System for the first time, which gives us an excellent opportunity to study their composition and origin. In this talk, I will explain the early classification for comets based on the basis of different dynamical and chemical properties. I will then explain the origin of a few long-period comets using the N-body dynamical simulation package, REBOUND. I will explain the N-body simulation code and benchmarking test with the well known asteroid, APOPHIS. I will conclude my talk with the inclusion of Non-gravitational forces and the difference with the results.

Magnitude and regulation of methane emission from tropical streams and rivers

Date

2025-04-24

Speaker

Dr. Latika Patel

Venue

Online

Abstract

Inland waters, particularly fluvial systems, are significant sources of atmospheric methane (CH4), a greenhouse gas with 34 times the global warming potential of carbon dioxide. However, large uncertainties persist regarding the extent and controls of CH4 emissions, especially in tropical river basins like those in Southeast Asia. Research work during my PhD addressed three critical knowledge gaps in understanding CH4 dynamics in tropical fluvial systems: (1) the effect of land use changes on CH4 concentration and emissions, (2) the occurrence and regulation of oxic CH4 production (OMP), and (3) the extent and environmental controls of aerobic CH4 oxidation (MOX), which will be discussed during the seminar.

Advances in Direct Imaging of Exoplanets

Date

2025-04-23

Speaker

Dr. Prashant Pathak

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Direct imaging of rocky exoplanets remains a major scientific objective for current and next-generation large telescopes. While existing facilities have successfully imaged young, Jupiter-mass exoplanets at wide separations (>0.1"), detecting smaller, rocky planets poses a significantly greater challenge due to the stringent contrast requirements. The mid-infrared (mid-IR) regime offers a promising solution, providing optimal planet-star contrast for detecting thermal emissions from exoplanets in our solar neighbourhood. In this talk, I will discuss the key techniques enabling direct imaging of exoplanets, with a focus on two mid-IR high-contrast imaging (HCI) instruments: NEAR (New Earths in the Alpha Cen Region) and METIS (Mid-infrared ELT Imager and Spectrograph). The NEAR experiment demonstrates the feasibility of HCI at ten microns, achieving sub-mJy sensitivity within a few hours—sufficient to detect multiple Jupiter-mass planets around nearby stars. I will present its operational principles and scientific outcomes. Furthermore, I will explore METIS, the first-generation instrument for the Extremely Large Telescope (ELT), highlighting its HCI capabilities and expected performance.

Origin of Soft excess in Mrk50

Date

2025-04-22

Speaker

Narendranath Layek

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Active galactic nuclei (AGNs) are the most luminous and energetic sources in the universe, powered by the accretion of matter onto supermassive black holes (SMBHs) located at the centers of host galaxies. The soft excess refers to an enhancement of flux in the soft X-ray range (below∼2 keV) over the primary power-law continuum, commonly observed in most Seyfert 1 AGNs. Its origin is a long-standing and unsolved puzzle in AGN studies. To investigate this, we conducted an extensive temporal and spectral analysis of the Seyfert 1 AGN Mrk 50, utilizing the observations from XMM, Swift, and NuSTAR. Two possible physical scenarios explain the origin of soft excess in AGNs , Warm Comptonization and Reflection from the ionized accretion disk. Both physical models successfully explained this behaviour in Mrk 50. Further, we investigated the origin using a model-independent approach using cross-correlation analysis between two X-ray bands (soft and hard) to examine the correlations and delays between them. In this seminar, I will present a detailed study of the origin of the soft excess in Mrk 50, based on our temporal and spectral analysis.

Static structure factor and the dispersion of the Girvin-MacDonald-Platzman density mode for fractional quantum Hall fluids on the Haldane sphere

Date

2025-04-22

Speaker

P. Rakesh Kumar Dora, The Institute of Mathematical Sciences, Chennai

Venue

Room no: 469 (Main Campus)

Abstract

We study the neutral excitations in the bulk of the fractional quantum Hall (FQH) fluids generated by acting with the Girvin-MacDonald-Platzman (GMP) density operator on the uniform ground state. Creating these density modulations atop the ground state costs energy since any density fluctuation in the FQH system has a gap stemming from underlying interparticle interactions. We calculate the GMP density-mode dispersion for many bosonic and fermionic FQH states on the Haldane sphere using the ground state static structure factor computed on the same geometry. Previously, this computation was carried out on the plane. Analogous to the GMP algebra of the lowest Landau level (LLL) projected density operators in the plane, we derive the algebra for the LLL-projected density operators on the sphere, which facilitates the computation of the density-mode dispersion. Contrary to previous results on the plane, we find that, in the long-wavelength limit, the GMP mode accurately describes the dynamics of the primary Jain states."

Biogeochemical implications of Ocean Alkalinity Enhancement

Date

2025-04-22

Speaker

Ms. Shreya Mehta

Venue

Ground Floor Lecture hall

Abstract

Over the past few centuries, anthropogenic activities have significantly altered the global carbon cycle, leading to a ~ 50% increase in atmospheric CO2 concentration relative to the pre-industrial levels. This rise has contributed to a global surface temperature increase of approximately 1.1°C (IPCC, 2023). To limit the future warming, it is being widely acknowledged that in addition to immediate reduction in greenhouse gas emissions, excess CO₂ needs to be actively removed from the atmosphere through carbon dioxide removal (CDR) methods. One promising CDR approach is Ocean Alkalinity Enhancement (OAE), which involves the addition of alkaline mineral to the ocean to enhance the oceanic uptake of atmospheric CO2 and is subsequently stored as dissolved inorganic carbon (DIC) over long periods. In addition to CO2 removal, OAE may also help mitigate ocean acidification by increasing the pH of water. Despite its potential, significant uncertainties remain regarding the feasibility, effectiveness, and environmental implications of implementing OAE at a global scale. To address these knowledge gaps, we conducted mesocosm experiments in the coastal waters of the Arabian Sea. These experiments aimed to investigate the effects of OAE on the carbon (C) and nitrogen (N) biogeochemical cycles within the marine ecosystem. In this seminar I will present some preliminary findings on how OAE influences carbon and nitrogen uptake rates in the coastal regions of the Arabian Sea.

Investigating the explosion and progenitor properties of Type II core-collapse supernovae

Date

2025-04-17

Speaker

Dr. Bhavya Ailawadhi

Venue

Online:https://imeet.vconsol.com/join/9563852195?be_auth=NDU5MzEx

Abstract

This presentation highlights the core components of my doctoral research, which focused on the photometric and spectroscopic characterisation of Type II core-collapse supernovae (CCSNe) and the development of automated data processing tools for time-domain surveys. CCSNe are end stages of massive stars, contributing to the chemical enrichment of the interstellar medium and influencing galaxy evolution through the dispersal of heavy elements. I conducted detailed observational studies of two transitional SNe—2020aze and 2020jfo—which do not fit cleanly into the classical Type IIP or Type IIL categories. SN 2020jfo exhibited a shorter plateau duration but shared key properties with Type IIP SNe. At the same time, SN 2020aze displayed characteristics that were more aligned with Type IIL SNe, including early flash features and a faster decline during the photospheric phase. These analyses contribute to the growing understanding that Type IIP and IIL SNe form a continuum rather than distinct classes. To investigate the role of progenitor environments, I conducted a statistical study on a broader sample of SNe by estimating metallicities using Fe line equivalent widths. This analysis provided insights into how progenitor metallicity influences light curve morphology and explosion characteristics. Complementing the observational work, I developed a fully automated aperture photometric pipeline in Python for the 4.0m International Liquid Mirror Telescope (ILMT). The pipeline processes time-delay integration (TDI) mode data, performs astrometric calibration, computes instrumental magnitudes, and derives calibrated light curves using catalogues like Pan-STARRS and SDSS. The pipeline is fully functional and is being used to derive long term light curves of variable sources.

Global Detection of Lunar Pyroclastic Deposits (LPDs)

Date

2025-04-11

Speaker

Mr Dibyendu Misra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Lunar Pyroclastic Deposits (LPDs) are fine-grained, low-albedo, Fe-Ti-rich volcanic glass-dominated lithological units typically associated with thin crust and extensional tectonic regimes on the Moon. These deposits are providing key insight into thermal evolution and volatile inventory of the Moon. However, their remote detection remains challenging due to the spectral similarities between volcanic glasses and Fe-bearing common lunar minerals (e.g., Olivine, Pyroxene, etc.) in the visible to near-infrared (VIS-NIR) spectral range. In this seminar, I will present a novel approach developed for remote detection of LPDs by incorporating morphological understanding with the spectral analysis covering both the spectral parameters. I will present new global​ LPDs maps, based on the Moon Mineralogy Mapper (M3) data of two different optical periods. The results will be validated by comparing the global outcomes to already reported LPDs. The main outcome of this work is new​ detections. I will present a few case studies on new detections and validation to confirm their pyroclastic origin. I will also discuss the inferences and implications during this seminar.

Higher-Order QCD Corrections and Threshold Resummation for Processes in the Standard Model and Beyond at Hadron Colliders

Date

2025-04-11

Speaker

Chinmoy Dey, IIT Guwahati

Venue

Online--- https://imeet.vconsol.com/join/9927407570?be_auth=NjU4MDkx

Abstract

In this talk, we present our study on threshold resummation for various Standard Model processes at the Large Hadron Collider (LHC), including neutral and charged Drell-Yan production, Higgs boson production in association with a massive vector boson, and Higgs production via bottom quark annihilation. We perform resummation up to N³LO+N³LL accuracy in QCD, addressing the large logarithms that arise in the partonic threshold limit. Additionally, we analyzed the gluon fusion channel for ZH production, resumming contributions up to NLO+NLL accuracy in the Born-improved theory and combining them with Drell-Yan-type contributions. For on-shell ZZ pair production, we extend the resummation accuracy to NNLO+NNLL. After performing the threshold resummation, the theoretical uncertainties are reduced compared to fixed-order results. Furthermore, we investigate the two-loop corrections to the decay of a pseudo-scalar Higgs boson (A) into three partons, including higher-order terms in the dimensional regulator. These results are crucial for improving theoretical predictions for pseudo-scalar production with one jet at hadron colliders.

Delving into the Extremes of Neutron Stars: Insights from Thermonuclear X-ray Bursts

Date

2025-04-08

Speaker

Dr. Gaurava Kumar Jaiswal

Venue

Online:https://imeet.vconsol.com/join/2150369168?be_auth=NTI3ODEz

Abstract

Neutron stars (NSs) are ultra-dense remnants of massive stars, characterized by immense gravitational fields, temperatures, and densities, making them unique laboratories for studying matter under extreme conditions. Type-I X-ray bursts, observed from accreting NSs in low-mass X-ray binary systems, provide valuable insights into these environments. These bursts are driven by unstable thermonuclear burning of accreted hydrogen and/or helium on the NS surface, typically lasting from tens to hundreds of seconds, depending on the fuel composition. About 20% of these bursts are energetic enough to temporarily lift the NS photosphere by tens to hundreds of kilometers. Additionally, the nuclear burning during the bursts leads to the synthesis of elements as heavy as those in the Sn-Sb-Te mass region. Studying these events offers critical information about nuclear processes, burst-accretion disk interactions, and provides important constraints on NS properties such as spin and compactness. Observations from the Neutron Star Interior Composition Explorer (NICER) have advanced our understanding by offering unprecedented timing and good spectral sensitivity, enabling detailed studies of X-ray bursters. This talk will focus on the latest NICER findings, highlighting the complex interplay between X-ray bursts, accretion dynamics, and nucleosynthesis, and how these observations can help constrain the equation of state of NSs - the "holy grail" of NS physics.

Anatomy of Monsoon Break Spells: A Probabilistic Approach

Date

2025-04-08

Speaker

Mr. Akash Ganguly

Venue

Ground Floor Lecture hall

Abstract

The Indian Summer Monsoon (ISM) is vital to India’s economy, and is intrinsically linked to the dreams and aspirations of over a billion people residing in the Indian subcontinent. Several causal mechanisms operating at differing spatio-temporal scales dictate the ISM performance, driving large inter-annual variability. Since the turn of the century, there has also been a conspicuous rise in both the frequency as well as intensity of extreme events, marking a discernible shift from the climatological trends. Such events have significant consequences necessitating the need for improved understanding of the causal mechanisms, as well as improved forecast skill for efficient water resources management. One such type of climatic extremes: the ‘monsoonal breaks’ are marked by a pause in the ISM synoptic system, resulting in reduced overall rainfall, and are accompanied by suppressed convection over the Monsoon Core Zone (MCZ), extended dry periods, heatwaves, and severe droughts as a direct consequence. However, the spatio-temporal pattern of rainfall distribution over the MCZ exhibit significant variability. Due to this inherent unpredictability and randomness, analyses often focus on aggregated rainfall data to discern broader trends and patterns. In this study, we demonstrate that the seemingly random pattern of rainfall, when analysed at small (1̊X1̊) spatial scales is indeed information rich, which can be efficiently churned out with the help of simple statistical tools. We find that the divergence of the rainfall distribution from the climatological trend exhibits symmetries. This information, which is otherwise averaged out can be leveraged to gain novel insights into the underlying causal mechanisms, thereby contributing to improved skill of forecasting extended monsoonal breaks. We extend the analysis to map the rainfall anomalies to the corresponding anomalies in the mean wind field, thereby identifying the dominant pathways of anomaly propagation and further extending the possible scope of forecasting such precipitation extremes.

The Role of Layered Minerals in the Origin of Life Insights from Planetary Analogue Terrestrial Geomaterials​

Date

2025-04-07

Speaker

Dr Amritpal Singh Chaddha

Venue

online

Abstract

How did life begin? Researchers believe that certain minerals, especially clays, played a big role in this process. These minerals can hold onto organic molecules, help chemical reactions happen, and create safe spaces for early life to form. Since they exist on Earth and other planets, they also help us search for signs of life beyond our planet. These layered minerals, abundant in terrestrial and extraterrestrial environments, serve as key indicators of fluid-rock interactions and potential biosignature preservation. This talk will explore how clays can serve as one of the potential planetary analogue terrestrial geomaterials that can enhance our understanding of life’s emergence. By employing comprehensive biogeochemical fingerprinting, this research will characterize clay minerals in terrestrial settings, assessing their capacity to preserve biosignatures. By studying layered minerals on Earth and extending these findings to available extraterrestrial samples, we can unveil the largely unexplored role of clay minerals in the origin of life, which is essential for planning future astrobiological missions.

Towards a Unified Understanding of Accreting Compact Objects

Date

2025-04-07

Speaker

Dr. Aru Beri

Venue

Online:https://imeet.vconsol.com/join/8175021695?be_auth=MzAwMTg1

Abstract

Accreting neutron stars and black holes in X-ray binaries are powerful laboratories for exploring extreme physical conditions such as strong gravity, dense matter, and intense magnetic fields. In this talk, I will present recent discoveries from fast X-ray timing and spectral observations, including coherent and incoherent variability that reveals the nature of the innermost regions of these systems. Drawing on results from the AstroSat survey, I will highlight the discovery of an intermittent accretion-powered millisecond X-ray pulsar (AMXP)—a transient source and potential gravitational wave emitter. I will also explore the role of transient events, such as outbursts, in advancing our understanding of accretion processes and how multi-wavelength campaigns help capture the dynamic behavior of both neutron star and black hole systems. Finally, I will discuss the potential of combining X-ray polarization with timing-spectral and multi-band observations to build a more complete picture of both persistent and transient accreting compact objects.

A Monte Carlo Approach to Temperature and Spectral Energy Distribution in Protoplanetary Disks

Date

2025-04-04

Speaker

Mr Soumik Kar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

A protoplanetary disk is a rotating circumstellar disk of dense gas and dust surrounding a young star. Understanding the structure and composition of these disks is essential for understanding the processes involved in planet formation. Over the years, various models have been developed to describe the chemical and hydrodynamic processes occurring within these disks. Here, we introduce a Monte Carlo Radiative Transfer (MCRT) model to characterize the temperature distribution and spectral energy throughout the disk and its surrounding envelope. MCRT method provides an efficient means of achieving radiative equilibrium without iteration in systems with temperature-independent opacity sources. Additionally, the computational time required for this method is comparable to that of pure scattering models. The MCRT approach tracks individual photon packets, allowing for precise identification of energy absorption sites and subsequent adjustments to local cell temperatures. To enforce radiative equilibrium, each absorbed packet is instantly re-emitted, with its frequency selected to correct the cell’s thermal spectrum. These re-emitted packets can undergo scattering, absorption, and re-emission processes until they escape, enabling the system’s temperature and spectral energy distribution (SED) to reach equilibrium. We present the initial results of the simulations for both spherical symmetry models and 2D axisymmetric density structures, comparing the findings with standard benchmark tests.

FIELD-ANGLE OPTIMIZED DESIGN FOR WIDE-FIELD IMAGING X-RAY TELESCOPES

Date

2025-04-03

Speaker

Mr. Neeraj K. Tiwari

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Wide field of view (FOV) imaging X-ray telescopes play a crucial role in addressing some of the most challenging and unresolved questions in modern astrophysics. For example, they are crucial for probing the early formation of supermassive black holes (SMBH), rigorously testing the hypothesis that nanoflares are the primary mechanism sustaining coronal temperatures above million Kelvin, and detecting the electromagnetic counterparts of gravitational wave events. However, existing optical designs for X-ray telescopes, such as the Wolter type-1 (W1) and Wolter-Schwarzschild (WS) configurations, offer high angular resolution only along the optical axis and are therefore limited to narrow FOVs (a few arcminutes), while the scientific cases mentioned above require high angular resolution across a much wider FOV (up to 60 arcminutes). In this talk, I will introduce a new optical design, the field-angle optimized (FO) design, specifically developed for wide FOV X-ray imaging telescopes. I will discuss the methodology behind this design, compare its performance with existing optical designs, and explore its feasibility for implementation in wide FOV solar X-ray telescopes.

Time domain photometric study of peculiar Blazars

Date

2025-04-01

Speaker

Dr. Shubham Kishore

Venue

Online: https://meet.google.com/ihi-bmxq-syc

Abstract

Blazars often exhibit random, aperiodic, and stochastic behaviours in their flux across all observational electromagnetic (EM) bands over a wide range of timescales. However, the underlying causes are not yet fully understood regarding which flux variations on the intra-day/day timescales are most poorly comprehended. These variations are primarily related to accretion or jet physics, as jets are powered by accretion. In the talk, I will elucidate my findings that include the quasi-periodic oscillatory signatures and flare episodes detected in three individual Blazar candidates observed with Transiting Exoplanet Survey Satellite (TESS).

Habitat Selection by Early Humans in the Indian Subcontinent

Date

2025-04-01

Speaker

Ms. Nandini Sharma

Venue

Ground Floor Lecture Hall

Abstract

The dispersal of our species out of Africa is believed to have occurred in multiple phases from the middle to late Pleistocene. Earliest fossil evidences for this migration of Homo sapiens is documented around 200-100 kya. These dispersals are influenced by the climate shifts, which shaped their habitats during migration. According to the Southern Dispersal Hypothesis, the dispersal of Homo sapiens from Africa into South Asia (130–75 kya) coincided with periods of favorable monsoon-driven green corridors, which influenced migration pathways and habitat selection. In this seminar, we will explore hominin habitat selection patterns by reconstructing woody cover along these dispersal routes using pedogenic carbonates as a vegetation proxy, providing insights into the environments they might have encountered and adapted.

Identification of Whistler Waves Near Flux Ropes in the Nightside Magnetosphere of Venus

Date

2025-03-28

Speaker

Ms. Aarti Yadav

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Whistler waves are electromagnetic plasma waves which are generated by temperature anisotropy instability in magnetized plasma. These right-handed circularly polarized waves propagate along the ambient magnetic field in a magnetized plasma. Atmospheric lightning has been considered a natural source of whistler waves at Venus. Recent observations from the Parker Solar Probe (PSP) during its fourth Venus Gravity Assist (VGA) detected whistler wave bursts in the Venusian magnetotail, with further analysis indicating a non-planetary origin. Magnetic reconnection, a fundamental plasma process which may be responsible for atmospheric erosion and dynamic magnetic activity in Venus' induced magnetosphere, emerges as a potential candidate. Observations at Earth have detected whistler waves near magnetic reconnection regions. Venus Express observed magnetic flux rope structures, which are formed by reconnection in Venus' magnetotail. This study explores the detection of whistler waves in the vicinity of these flux rope structures, bridging the concept of whistler wave generation via magnetic reconnection at Venus.

Banded Iron Formations: Archives of Precambrian ocean-atmospheric redox conditions

Date

2025-03-25

Speaker

Dr. Ajay Dev Asokan

Venue

Ground Floor Lecture Hall

Abstract

Banded Iron Formations (BIFs) are chemical sedimentary rocks with alternating silica and iron-rich bands. The composition of well-preserved BIFs records the seawater composition from which they precipitated and hence, can be used to infer the evolution of Precambrian ocean, ocean-atmospheric redox conditions as well as the emergence of continental crust. Based on associated litho units, BIFs are classified mainly into two variants, i.e., Algoma-type BIFs, that are associated with volcano-sedimentary sequences and Superior-type BIFs, that are associated with clastic sediments. In this presentation, I’ll discuss about different views on BIFs, including the origin of their banding, primary mineralogy and post-depositional alteration, with a focus on trace element compositions of Superior-type BIF from the Bastar Craton and Algoma-type BIF from the Dharwar Craton. The BIFs from the Bastar Craton records Archean seawater compositions, while those from the Dharwar have been significantly modified by post-depositional alteration.

Hidden’ magnetism and a mechanism for it

Date

2025-03-25

Speaker

Dr. Aabhaas Vineet Malik, Birla Institute of Technology and Science Pilani, KK Birla Goa campus

Venue

Room no: 469 (Main Campus)

Abstract

Recently a mysterious hidden magnetic memory, which manifests itself in the form of “spontaneous” vortices appearing in the superconducting state of 4Hb-TaS2, was reported [Nature, 607,692, 2022]. Motivated by this observation, we present a mechanism which leads to a similar phenomenology. The mechanism relies on spin-charge separation induced by strong electronic correlations in a flat-band tuned away from half filling, which is the expected picture of the T-layers in 4Hb-TaS2. For concreteness, we demonstrate the feasibility of this mechanism within a square lattice t-J model. Our results pave the way towards understanding the observed magnetic memory effect and may apply to a broader class of materials.

Towards Quantum Simulating QCD

Date

2025-03-25

Speaker

Dr. Indrakshi Raychowdhury, Birla Institute of Technology and Science Pilani, KK Birla Goa campus

Venue

Room no: 469 (Main Campus)

Abstract

Being created from the Big Bang - evolved to families of sub-atomic particles - landing in an astrophysical environment -the dynamic properties of the strong interactions of nature are still unknown. Simulating the dynamics of quantum chromodynamics (QCD) is beyond the scope of even the most powerful supercomputers. Standing at the end of the first quarter of the century, the question is whether a quantum computer can (/will be able to) simulate nature. Okay, yes, it should. The visionary physicist Richard P. Feynman envisioned that "Nature isn't classical, dammit, and if you want to make a simulation of nature, you'd better make it quantum mechanical..." After almost half a century as quantum technology matures it appears to be close to a reality. Yet, as Feynman envisioned, the task remains challenging and requires substantial advancement in `qubitizing/quditizing’ nature - develop novel quantum algorithms and implement them on quantum hardware. In this talk, I'll briefly summarize the journey towards quantum simulating QCD - the challenges, advances and prospects.

​Electrostatic Dust Detachment

Date

2025-03-21

Speaker

Mr Trinesh Sana

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The electrostatic processes are fundamentally important in understanding particle dynamics and the complex dusty plasma environment over the Moon. While many studies have examined dust levitation, the detachment of dust from the lunar surface remains a key factor in understanding the lunar dusty plasma environment. Dust particles on the charged lunar surface experience gravity, cohesion, and electrostatic forces. Typically, the electrostatic force derived from a uniformly charged surface (from Gauss Law) is insufficient to lift the particles against gravity. In this presentation, I will demonstrate that sufficient electric field and coulomb repulsion can be created between the dust and surface due to charge fluctuations on a microscopic scale, which can detach the dust particle from the lunar surface, overcoming dust-surface adhesive force.

From Monopole-Induced Berry Phase to Quadrupolar Berry Phase

Date

2025-03-21

Speaker

Prof. Sourin Das, Indian Institute of Science Education and Research, Kolkata

Venue

Room no: 469 (Main Campus)

Abstract

We explore the Berry phase associated with purely quadrupolar states (⟨ψ|S|ψ⟩ = 0) in spin-1 systems. By employing the Majorana stellar representation, we demonstrate the topological nature of the quadrupolar Berry phase, revealing that it takes values of either 0 or π, and establish its connection to the exchange of Majorana stars. Additionally, we investigate the dynamics of a state within the quadrupolar subspace under the influence of a static magnetic field. The time evolution governed by this Hamiltonian confines the system to the quadrupolar subspace, generating a geometric phase of the Aharonov-Anandan type, quantized to 0 or π. We also present a natural framework for understanding the topological properties of this subspace in terms of anti-unitary symmetries. Finally we will discuss a possible application of our findings to Holographic quantum codes and robust quantum phase gates.

The African Network of Women in Astronomy (AfNWA) and SciGirls: Examples of social activism

Date

2025-03-20

Speaker

Dr. Mirjana Povic

Venue

Online: https://meet.google.com/cuw-pwht-zej

Abstract

The world faces a significant gender gap in science. In Africa, in average the population of female scientists is below 25%. The African Network of Women in Astronomy (AfNWA) is an initiative that aims to connect women (or people who identify as such) working in astronomy and related fields in Africa. It was established in September 2020 as one of the committees of the African Astronomical Society (AfAS). With AfNWA we want to ensure the future participation of girls and women at all levels in the development of astronomy and science in Africa. Our main goals are to improve the status of women in science in Africa and to use astronomy to empower girls and women, and to inspire more girls to pursue Science, Technology, Engineering and Mathematics (STEM). This talk will summarise the activities carried out by AfNWA and the current status of women in astronomy in Africa. It aims to give visibility to the work and achievements of the AfNWA community, and the various activities carried out across the continent to support girls and women living and working in under-represented communities through astronomy. In Ethiopia, only about 13% of all scientists are women, and this fraction is even lower when considering the fundamental sciences. Girls avoid choosing STEM mainly due to a lack of support and/or information. This becomes even more evident when going to remote areas, where 80% of the Ethiopian population lives. The SciGirls project aims to improve the gender gap in science in the long-term by empowering female secondary school students and their female science teachers who are working and living in remote and rural areas through astronomy and its multidisciplinarity. In 2022 and 2024 we organised a carefully designed capacity-building workshop for 60 participants across Ethiopia, with the aim of training future STEM advocates in rural and remote areas. The girls and teachers carried out different activities in their communities after the training. Most of participants came from the regions that have been severely affected by conflicts over the past 4 years. SciGirls is one of the 2022 and 2024 projects funded by OAD. During this talk, we will share valuable experiences we have gained through interaction with girls and female teachers who work and live in very harsh conditions, where they rarely have any external support to fulfill their dreams. The SciGirls approach has so far yielded very positive results and the project can serve as a model also in other countries.

Gamma-Ray Bursts (GRBs) as electromagnetic (EM) counterparts of Gravitational Wave (GW) sources

Date

2025-03-06

Speaker

Dr. Suman Bala

Venue

Room No. 113, Thaltej

Abstract

Gamma-Ray Bursts (GRBs) are the brightest explosions in the Universe since the Big Bang. We have comprehensive knowledge about the GRBs, but there are many open questions even after fifty years of the first detected GRB, especially about the prompt emission phase. The detection of gamma-ray burst GRB 170817A by Fermi-GBM, coinciding with gravitational wave (GW) GW170817, is one of the extraordinary discoveries in the history of the multimessenger era. It is not only the first binary neutron star (BNS) merger detected by the advanced (LIGO-Virgo) GW detectors; it is the only GW detection with a confirmed electromagnetic (EM) counterpart. The Fermi Gamma-ray Burst Monitor (GBM) is an all sky monitoring instrument sensitive to photon energies from 8 keV to 40 MeV. Its capabilities makes it ideal for providing simultaneous gamma-ray observations of gravitational-wave transients. Fermi-GBM continues to look for similar multimessenger detections through on-board triggers as well as subthreshold searches for weak transients, performed both in high-time-resolution continuous data and in targeted follow-ups of gravitational-wave events. In this talk, I will present an overview of GRBs and recent results from targeted and subthreshold searches as a counterpart of GW events.

Hot Jupiter Exoplanets: The Enigmatic Giants of Astrophysics

Date

2025-03-04

Speaker

Dr. Soumya Sengupta

Venue

Room No. 113, Thaltej

Abstract

Since the discovery of the first exoplanet, 51 Pegasi b, Hot Jupiters (HJs)—Jupiter-like exoplanets orbiting close to their host stars—have remained a central focus in exoplanetary science. Unlike planets in our solar system, these unique systems allow us to study them directly through their infrared emission. Due to intense stellar irradiation, Hot Jupiters exhibit extremely high temperatures, resulting in distinct emission spectra originating primarily from their day-side hemispheres, especially in tidally locked systems. Analyzing these emission spectra provides valuable insights into the temperature structure and chemical composition of these intriguing exoplanets. However, the overlap between planetary and stellar emissions poses a persistent challenge for planetary atmospheric modeling. Additionally, the strong day-night atmospheric flow, driven by the extreme temperature contrast between hemispheres, introduces variability in the observed emission spectra. Another intriguing feature of Hot Jupiters is their larger observed radii compared to Jupiter; a phenomenon known as the radius inflation problem. In this talk, I will explore these fascinating questions surrounding Hot Jupiters, using fundamental physics concepts to unravel the mysteries of these extraordinary worlds.

Echoes of the Ancient Earth: A Quarter Century of Exploring the Vindhyan Basin’s Secrets

Date

2025-03-04

Speaker

Dr. Jyotiranjan S. Ray

Venue

Ground Floor Lecture Hall

Abstract

The first known animal life on Earth dates back to 630 million years. However, in 1998, a couple of fossil discoveries shook the geoscience world with their spectacular claims of the presence of advanced animal life in rocks of the Vindhya mountains that were generally considered to be older than 1100 million years. These findings sparked intense controversies about their legitimacy and the host rocks' ages. We took up the challenge of dating these rocks deposited in India's largest Proterozoic sedimentary basin. In the last 25 years, we have not only been able to resolve the chronology of the Vindhyan Supergroup, but also made many significant contributions to the study of regional stratigraphy and environment, ocean chemistry and tectonics during the Proterozoic. In the talk, I shall share some of our important findings.

Unravelling Mar’s Magmatic Past: Insights from Martian Shergottites

Date

2025-02-28

Speaker

Ms Varsha M Nair

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Shergottites, constituting around 90% of the Martian meteorite collection, are categorized into various types: basaltic, olivine-phyric, poikilitic, and gabbroic. Notably, poikilitic shergottites are distinct from the other shergottites as they are cumulate and form at the deep interior into the Mars in comparison to the other extrusive members. This study delves into the mineralogy and petrology of a poikilitic shergottite, NWA 1950 to constrain Martian igneous processes and identify mantle source reservoirs for shergottites. Additionally, the olivine-hosted melt inclusions help to constrain parental melt compositions, mantle sources, and formation processes, while also reconstructing magma evolution from emplacement to ascent.

Health risks of air pollution in a warming climate: Current evidence and New directions

Date

2025-02-26

Speaker

Dr. Sagnik Dey

Venue

Ground Fllor Lecture Hall

Abstract

Air pollution has been identified as the leading environmental health risk globally. In India, air pollution has been identified as the second largest health risk after maternal and child malnutrition. Health risks attributable to air pollution require robust exposure estimates, sociodemographic conditions and background disease rates. The Global Burden of Disease (GBD) Study has provided a robust framework to estimate the health burden of air pollution. However, the current estimates, available at state levels, have two critical assumptions. First, the risk is considered to be uniform across the composition, neglecting the issue of particle toxicity. Second, the exposure-response functions are derived from cohorts primarily conducted in developed countries. Lack of robust exposure data hindered the generation of India-specific exposure-response functions for non-communicable diseases. In this talk, I will demonstrate the recent advancements in exposure modelling and how such data is being used for health studies, addressing these two aspects. I will also highlight the complex pathways between air pollution and climate and how the air pollution attributable burden is expected to change in future. My talk will demonstrate the urgent need for a collaborative and systematic approach to understand and minimise environmental health risks in India.

​Identification and Characterization of Topside V3 Layer of Venusian Ionosphere

Date

2025-02-14

Speaker

Satyandra Mohan Sharma

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The dayside Venusian ionosphere is produced by photoionization (primary) and photoelectron impact (secondary) ionization from solar EUV (10-105 nm) and SXR (0.1-10 nm) radiations producing V2 (~140 km) and V1 (~125 km) layers. Previous observations from missions such as the Mariner, Venera, and Pioneer Venus Orbiter also reported a "bulge" at 160–200 km altitudes. This bulge has not been documented in any of the standard ionospheric model. Moreover, there have been a limited data of the ionospheric observation during low solar activity which further constrain the characterization of this V3 layer. Using electron density profiles observed by VeRa radio occultation experiment under varying solar activity levels and solar zenith angles (SZAs), we examined the bulge, known as the "V3 layer". Our study analyzed over 200 electron density profiles to characterize this V3 layer. In this seminar I will briefly summarize the results of V3 layer morphology and occurrence rate under varying Solar activity and SZA conditions.

Fabry-Perot wavelength calibration system for precise radial velocity measurements

Date

2025-02-13

Speaker

Shubhendra Nath Das

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Although more than 5000 exoplanets have been detected, only a few have had their profiles constructed. Besides the radius, mass is significant variable as well, which makes the radial velocity (RV) method important. Yet, instruments and calibration of the equipment pose constraints when it comes to the detection of small Doppler shifts (sub-m/s). One such issue is the accuracy of the wavelength calibration itself. Addressing this, the cost-effective and stable Fabry-Pérot (FP) etalons are an alternative to uranium-argon (UAr) lamps because they last significantly longer and have a spectrum that is ideal for supporting better wavelength calibration for very precise RV measurements. We are changing PARAS-2’s calibration system from UAr to FP. In this seminar, we will give project progress report and show laboratory testing outcomes of the FP system.

LCSR application to D+ → π+l+l−

Date

2025-02-13

Speaker

Dr. Anshika Bansal

Venue

Room no: 469 (Main Campus)

Abstract

Flavour Changing Neutral Currents (FCNCs) in the Standard Model (SM) arise only at loop level, making them important probes for New Physics (NP). However, unlike bottom FCNCs (for example b → s l+l−), the charm FCNCs (for example c → u l+l− ) are dominated by long distance (LD) effects due to strong GIM suppression, posing significant challenges. In this talk we will explore these challenges focusing on decays D+ → π+l+l− which can be realised as the combination of the singly Cabibbo suppressed (SCS) weak transitions with the electromagnetic emission of the lepton pair. We study these LD effects using the framework of Light Cone Sum Rules (LCSR) and make predictions for the differential widths for these decays. Our findings suggest that the weak annihilation contributions are dominant, with negligible loop contributions. Finally, I relate these decays to other Cabibbo favoured and doubly Cabibbo suppressed, D(s)+ → P l+l− (P = π, K... ) decays through flavour symmetries. As a byproduct, I further discuss Ds+ → π+l+l−, which is not an FCNC but shares the topologies with D+ → π+l+l−, and can therefore be useful in better understanding of LD dynamics involved.

Solar Coronal Phenomena: Imaging X-ray Spectroscopy

Date

2025-02-11

Speaker

Dr. Biswajit Mondal

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

The Sun's outer atmosphere, known as the corona, is significantly hotter than its surface, presenting a long-standing scientific mystery. One hypothesis is that small, frequent bursts of energy, called nanoflares, may be responsible for this heating, though the exact mechanism remains unclear. Additionally, certain elements in the corona appear more abundant than expected, a phenomenon termed the "FIP effect," which might also be linked to coronal heating processes. Imaging X-ray spectroscopy offers a powerful method for investigating these solar mysteries. In this talk, we will explore these intriguing questions about the Sun and discuss how imaging X-ray spectroscopy can provide insights. We will introduce the Marshall Grazing Incidence X-ray Imaging Spectrometer (MaGIXS) sounding rocket experiment and its recent successful flight, designed to probe these enigmatic aspects of the Sun.

Puzzles and predictions of the left right symmetric model

Date

2025-02-06

Speaker

Dr. Ravi Kuchimanchi

Venue

Room no: 469 (Main Campus)

Abstract

We will show that O(1) leptonic CP violation generates too large a strong CP phase in one loop RGE running, and therefore the Minimal Left Right Symmetric Model (with triplet and bidoublet Higgses) is testable regardless of the scale of parity breaking by the following prediction: The neutrino experiments will not discover leptonic CP violation in the PMNS matrix. Moreover the lepton mass hierarchy can be understood in this model if the electron mass is radiatively generated in 2 loop RGE.

Tides as a tool for deciphering internal structures of telluric planets

Date

2025-02-05

Speaker

Prof Agnès Fienga

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Modelling the tidal deformations observed on the telluric planets is a complementary approach to any seismological data to decipher their internal structure. It provides constraints on internal heterogeneities, as well as rheological and density constraints on materials, enabling tidal 'tomography'. These constraints, coupled with thermodynamic models, allow us to establish the current structure of these objects and help us to understand their geodynamic evolution. In this seminar, we will look at the internal structures of Moon and Mars cores, the process of mantle overturn during the crystallisation of the lunar magma ocean, the persistence of a potentially molten zone in the Martian mantle and the persistence of a significant viscosity contrast between the upper mantle of Venus and the lower mantle. We will also look at the viscosity contrasts between the Martian lithosphere and asthenosphere. The challenges of characterising the existence of heterogeinities in the Moon mantle will be also addressed.

Diffuse Interstellar Bands in the Milky Way as seen by GAIA

Date

2025-02-04

Speaker

Mathias Schultheis

Venue

Room No. 113, Thaltej

Abstract

Diffuse interstellar bands (DIBs) are interstellar absorption features originating from the interstellar medium, quasi-consensually attributed to large organic molecules. DIBs exist in the optical and in the infrared. Most of the DIBs show a tight relation with interstellar reddening, and can therefore be used as an excellent tracer of the ISM. Beside the equivalent width of the DIBs, radial velocities profiles can be derived and be used to study e.g the Galactic rotation curve of the carrier. I will present the capacity of the Gaia-Radial Velocity Spectrometer (RVS) in Gaia DR3 to reveal the spatial distribution of the unknown molecular species responsible for the most prominent DIB at 862\,nm in the RVS passband exploring the Galactic interstellar medium within a few kiloparsecs from the Sun. Nearly 500.000 DIB measurements have been obtained in a homogeneous way covering the entire sky, making it the largest sample of DIB measurements so far. I compare spatial distributions of the DIB carrier with interstellar reddening and find evidence that DIB carriers are present in a local bubble

Design and development of PRATHIMA electronics subsystem for LuPEX/Chandrayaan-5 Rover

Date

2025-01-31

Speaker

Chandan Kumar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Permittivity and Thermophysical Instrument for Moon’s Aquatic Scout (PRATHIMA) is an instrument onboard ISRO-JAXA LuPEX Rover. PRATHIMA experiment consists of three main sub-systems: (a) a permittivity probe that will be deployed into ~50 cm of the lunar surface (in a pre-drilled borehole), (b) electronics and (3) a deployment mechanism. The Probe consists of pairs of electrodes, which consist of a pair of transmitters and receivers. The complex permittivity of the Lunar Regolith over the low-frequency range (e.g. 1Hz-10 kHz) by measuring the mutual impedance between the transmitter and receiver electrodes. The subsurface complex permittivity (i.e., dielectric constant and conductivity) is derived from the measured phase and amplitude of the mutual impedance. The dielectric constant of water ice embedded in Lunar regolith strongly depends on the frequency in the 10 Hz-10 KHz range and temperature. The design aspects and its development status will be presented in the seminar.

Non-Fermi Liquid Transport in Semimetals and Strongly Correlated Systems

Date

2025-01-30

Speaker

Dr. Abhishek Samanta, IIT Gandhinagar

Venue

Room no: 469 (Main Campus)

Abstract

The Hall coefficient traditionally measures the density of charge carriers in metals, via Drude’s inverse carrier density relation. However, this relation may break down due to intriguing Fermi surface topology or strong electronic interaction. Using a recently developed thermodynamic formalism, we study deviations of the Hall coefficients from Drude's relation in (1) semimetals (e.g., Weyl, nodal-line) and (2) the Hubbard model. Our calculations explain the "Hall anomaly", characterized by a divergence of the Hall coefficient near half-filling and an abrupt sign change, observed in cuprate experiments. Finally, I will briefly discuss similar anomalies in thermopower, studied via the calculation of the Seebeck coefficient of strongly interacting systems.

Biogeochemistry of the Arabian Sea since JGOFS

Date

2025-01-28

Speaker

Prof. Sanjeev Kumar

Venue

Ground Floor Lecture Hall

Abstract

The Arabian Sea is one of the most productive oceanic basins of the world. Most of our understanding related to physical, chemical and biological aspects of the Arabian Sea was developed during the Joint Global Ocean Flux Studies (JGOFS) program in the early 90s. This talk will delve upon some of the landmark findings of that era and progress made, if at all, since then.

​Transmitter electronics of Permittivity and Thermophysical Instrument for Moon’s Aquatic Scout (PRATHIMA)

Date

2025-01-24

Speaker

Sushil Kumar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

PRATHIMA is one of the selected payloads for the LUPEX/Chandrayaan-5 mission. Its primary objective is to detect and quantify regolith-bound water-ice on the lunar surface/subsurface in the vicinity of the landing site, along the traverse of the rover. The working principle of PRATHIMA involves measuring the dielectric permittivity of water-ice at low frequencies, as water-ice exhibits a significantly high dielectric permittivity in this range. Therefore, a low-frequency sinusoidal signal can be used to excite a medium to study the presence of water-ice content mixed with the regolith.A transmitter electronics system has been designed to generate a programmable low-frequency sinusoidal signal using an FPGA-based Direct Digital Synthesis (DDS) algorithm.

Exploring the Dynamics of Oxygen Minimum Zones in the Bay of Bengal over the last 25 ka

Date

2025-01-21

Speaker

Dr. Deepak Kumar Rai

Venue

Ground Floor Lecture Hall

Abstract

Anthropogenic warming has significantly reduced oceanic oxygen levels, raising concerns about the expansion of Oxygen Minimum Zones (OMZs) and their impact on marine habitats. The northern Indian Ocean hosts one of the world's three major OMZs, with pronounced oxygen-deficient conditions in the northeastern Arabian Sea. In this region, dissolved oxygen levels drop below 10 nM at intermediate depths, intensifying anaerobic processes such as denitrification and ammonium oxidation (anammox). These processes contribute to the loss of bioavailable nitrogen and nitrous oxide production—a potent greenhouse gas. In contrast, while dissolved oxygen concentrations in the Bay of Bengal fall below 20 &#956;M, evidence for nitrogen loss processes remains inconclusive. However, the Bay of Bengal OMZ is considered to be at a geochemical tipping point, where further oxygen depletion—driven by anthropogenic nutrient input or climate change—could amplify its role in the marine nitrogen cycle by triggering nitrogen loss processes. Natural mechanisms influencing OMZ variability, aside from global warming, remain poorly understood, likely due to limited observations that are already influenced by anthropogenic signals. Therefore, it is essential to explore long-term OMZ variations under diverse climatic conditions through paleo reconstructions, which can provide crucial insights into the natural variability of OMZs, aiding in more accurate future predictions. In this talk, I will discuss the current understanding of OMZ dynamics in the northern Indian Ocean and highlight key research gaps in the field.

In-In EFT, the In-Out way

Date

2025-01-21

Speaker

Prof. Namit Mahajan

Venue

Room no: 469 (Main Campus)

Abstract

In-In correlators are the natural quantities in time dependent settings like cosmology or in non-equilibrium situations when the interest in not in scattering matrix elemnts but rather expectation values. The talk will describe an attempt to have an effective field theory (EFT) description for In-In correlators in terms of the more familiar In-Out formalism routinely used for S-matrix calculations.

Characterization of Multichannel SDD X-Ray Spectrometer with ASIC Readout

Date

2025-01-17

Speaker

Nishant Singh

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

In the seminar, I will present the development of a multichannel Silicon Drift Detector (SDD) based X-ray spectrometer with application-specific integrated circuit (ASIC) readout aimed at flying in future space missions. The multiple channels facilitate the spectrometer to have a large detection area, allowing the detection of faint X-ray sources. The spectrometer is designed to readout the signal from eight SDDs through a VErsatile Readout for Detector Integration (VERDI) ASIC with high energy resolution in the 1-25 keV energy range. The spectrometer provides an X-ray spectrum for each detector simultaneously. Initially, the system is tested with five SDDs and shown that the spectrometer provides the energy resolution of ~148 eV at 5.9 KeV when SDDs are cooled to -35oC. We have also assessed the system’s performance for different detector operating temperatures and pulse shaping times. The detailed design and the performance assessment of the spectrometer will be presented in the seminar.

Radio eyes for the Sun, Heliosphere and Ionosphere: Status and plans for the LOFAR2.0 era.

Date

2025-01-17

Speaker

Dr. Pietro Zucca

Venue

USO Seminar Hall

Abstract

The Low-Frequency Array (LOFAR) has established itself as a formidable instrument in the field of solar physics and spaceweather, providing a unique vantage point for observing the Sun, heliosphere, and ionosphere. As we transition into the LOFAR2.0 era, this abstract outlines the current status and future plans for leveraging LOFAR's capabilities, and the LOFAR IDOLS (Incremental Development of LOFAR Space-weather) project.LOFAR's current work in solar physics involves high-resolution imaging and dynamic spectral analysis, enabling detailed observations of solar radio bursts and other coronal heliosphere and ionosphere phenomena. These observations are critical for understanding the mechanisms behind solar activity and improving our predictive models of space weather events. The LOFAR IDOLS station, a dedicated space-weather science facility, has been instrumental in advancing this work. It currently provides continuous monitoring of the ionosphere and Sun, tracking disturbances that can affect space wetaher on Earth, but also the astronomical observations of LOFAR itself. The LOFAR2.0 upgrade promises to enhance these capabilities significantly. Plans include improving the sensitivity and spatial resolution of the array, and the simoultaneus observations in LBA and HBA, which will allow for even more precise and broad imaging and tracking of solar phenomena. This will enable researchers to dissect the fine structures within the solar corona and track the development of space weather events with greater accuracy. Furthermore, the LOFAR IDOLS project is set to continue observation during the period of transition to LOFAR2.0 enabling us to test the monitorning capabilities. In conclusion, the LOFAR2.0 era opens a new opportunity for solar and space weather research. With the ongoing work and future plans for the LOFAR IDOLS station and LOFAR2.0 observations, we are preparing to gain deeper insights into the Sun's influence on our space environment and to develop more robust forecasting capabilities for space weather phenomena.

Exploding Stars, Shapeshifting neutrinos, and the Synthesis of Heavy Elements

Date

2025-01-16

Speaker

Dr. Amol V. Patwardhan, New York Institute of Technology, USA

Venue

Online--- https://imeet.vconsol.com/join/1447710668?be_auth=NTg3MTQz

Abstract

How exactly do stars explode? Where and how are the elements that we observe in the cosmos synthesized? A common theme tying these questions together is the abundant presence of neutrinos – mysterious and elusive elementary particles – in these environments. In this talk, I shall describe how neutrinos can power these magnificent cosmic explosions, i.e., supernovae, and also aid in the synthesis of heavy elements thereafter. Particular attention will be given to a longstanding open question: the origin of proton-rich isotopes in nature. I will present some interesting results from my recent work, demonstrating how a once-popular solution to this conundrum still endures, despite a decade's worth of claims to the contrary. Finally, I shall briefly discuss some peculiar behaviors of neutrinos, such as their penchant for shapeshifting (flavor oscillations), or their potential to quantum-entangle as they interact with each other in these environments.

Organic Matter Sulfurization Dynamics in Natural Systems

Date

2025-01-15

Speaker

Dr. Tushar Adsul

Venue

Online

Abstract

The sulfurization of organic matter is a globally significant biogeochemical process with far-reaching implications for the Earth's carbon, sulfur, and oxygen cycles. This process has been a subject of intense investigation due to its role in several critical areas: (1) petroleum formation and quality, (2) the coupled global biogeochemical cycles of carbon, sulfur, and oxygen, (3) sedimentary microbial activity, and (4) the preservation of organic matter and its application in molecularly based paleoenvironmental reconstructions. Despite its significance, our understanding of organic matter sulfurization remains incomplete. One major challenge in unraveling the sulfurization process is the immense diversity of organic sulfur compounds in nature, which form via various pathways. Sulfur can be incorporated intramolecularly into organic molecules, forming cyclo-sulfur compounds such as thiophenes or thianes. Alternatively, sulfur can be added intermolecularly, leading to macromolecular moieties linked by C-Sx-C bonds. This diversity complicates efforts to establish universal mechanisms for organic sulfur formation. Another critical challenge lies in the complexity of sedimentary sulfur cycling, which involves both biological and abiological processes. The precise source of sulfur incorporated into organic matter is not well understood. Whether pore-water sulfide, polysulfides, elemental sulfur, or a combination of these sources contributes to the sulfurization process remains unclear. The interactions among these sulfur pools and organic substrates further add to the complexity of the system. The sulfurization process is particularly significant in anoxic environments, such as marine sediments, where sulfate-reducing bacteria generate hydrogen sulfide. This reactive sulfide interacts with organic matter, stabilizing it by forming sulfur-rich compounds. These compounds, such as thiophenes, are resistant to degradation and play a vital role in the long-term preservation of organic matter in sediments. Furthermore, sulfurization contributes to the formation of sulfur-rich petroleum and coal, such as the Paleogene Superhigh-Organic-Sulfur Coals of Meghalaya, India. Recent advancements in analytical techniques are opening new avenues for understanding the mechanisms of organic matter sulfurization. The use of sophisticated tools such as GC-MS/FID/FPD for organic sulfur compound identification, coupled with compound-specific sulfur isotope analysis (CSIA), enables researchers to trace sulfur fractionation at the molecular level. These techniques help establish precursor-product relationships and provide insights into the pathways of sulfur incorporation into organic matter.

The Origin of Isotopes

Date

2025-01-10

Speaker

Mr Antariksha Mitra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The origin of isotopes plays a cruicial role in understanding the chemical enrichment of the Universe. Isotopes are formed through nucleosynthesis processes in stars, including stellar burning, supernovae, and neutron star mergers. These processes distribute isotopes into the interstellar medium (ISM), influencing the evolution of galaxies. Galactic Chemical Evolution (GCE) provides a framework to model the production, distribution, and recycling of isotopes over cosmic time, driven by processes such as star formation, stellar feedback, and gas inflow/outflow. In this seminar, I will discuss the primary sources of isotopes, the physics of their nucleosynthesis, and the mechanisms by which they are transported and mixed within galaxies. The talk will also explore the connection between isotope studies and the broader understanding of the Milky Way's formation and evolution.

On the Propagation of Shock Waves in the Transition Region and the Corona

Date

2025-01-10

Speaker

Mr. Ravi Chaurasiya

Venue

USO Seminar Hall

Abstract

The chromosphere exhibits various acoustic waves that are generated in the photosphere or deeper layers due to convective motions. As these waves encounter the steep density gradient between the photosphere and the chromosphere, they transform into shock waves, often characterized by a sawtooth pattern in λ-time plots of chromospheric spectral lines, such as Hα and Ca II. In this study, we investigate the formation and propagation of these shock waves in the chromosphere, examining their possible implications in the higher solar atmosphere using observations from the Multi Application Solar Telescope (MAST), the Swedish 1-meter Solar Telescope (SST), the Interface Region Imaging Spectrograph (IRIS), and the Solar Dynamics Observatory (SDO). Our results show that these shock waves are predominantly observed in or near magnetic flux concentration regions and can propagate at least up to the transition region. In this talk, I will discuss the identification of these shock waves, their propagation characteristics, and their potential implications for coronal dynamics.

Tracing Cosmic Origins: Unveiling Element Formation Through Stellar Archaeology

Date

2025-01-09

Speaker

Pallavi Saraf

Venue

Online: https://imeet.vconsol.com/join/8509176600?be_auth=NjMwMzQ4

Abstract

The origins and distribution of chemical elements in the Universe have long been a subject of investigation, with many unresolved questions remaining. The oldest stars in our Milky Way are rare relics from the early Universe, preserving the chemical imprints of the first stars and supernova explosions. These stars are crucial in addressing questions about element formation processes that occurred around 13 billion years ago. I will explain on how I employ "Stellar Archaeology": the use of observations and analysis of the chemical properties of the oldest stars in Galaxy, to answer outstanding questions about the early Universe and the origins of the chemical elements in the Cosmos. One of the significant unanswered questions in astrophysics is the site of the rapid neutron-capture process (r-process). While the optical counterpart AT 2017gfo of the kilonova GW 170817 did provide evidence of the r-process in neutron star mergers, important details are still unsolved. Neutron star mergers alone seem to be unable to explain r-process enrichment in the Universe, and there are still open questions with respect to their time scale. I will discuss some of the results from observations of r-process stars with the Gran Telescopio Canarias (GTC) and the Very Large Telescope (VLT), as well as CEMP-r/s stars observed with the KECK telescope and VLT. Additionally, I will share findings from the HESP-GOMPA survey conducted by our group. Finally, I will discuss how my expertise aligns with the facilities at the Physical Research Laboratory (PRL), such as PARAS-2.

Electron Density Mapping: Insights from Radio and In-Situ Observations & EUHFORIA Modeling

Date

2025-01-09

Speaker

Ms Ketaki Despande

Venue

USO Seminar Hall

Abstract

Mapping the coronal electron density remains a challenging task, as we still rely on rather old 1D electron density models, most of which are derived from remote sensing observations and lack validation with in situ measurements. The novel observations from Parker Solar Probe (PSP) provide a unique opportunity to validate these models and enhance space weather modeling capabilities. In this study, we analyze type III radio bursts observed during PSP’s second perihelion. By employing radio triangulation, we estimate the 3D radio source positions and map the electron densities along the burst propagation path. These results are then compared with in situ electron density measurements from PSP. Additionally, we use EUHFORIA (European Heliospheric Forecasting Information Asset) to model electron densities at the PSP location and the radio source positions. Our findings indicate that bursts occurring within a few minutes from the same source can exhibit significantly different propagation paths. A comparison between radio-derived and in situ densities reveals a discrepancy of one order of magnitude. We also perform simulations using GONG and ADAPT-GONG magnetic maps as input. Both simulations suggest that type III bursts propagate along higher-density regions; however, results obtained with ADAPT-GONG maps show a better match with PSP in situ densities and predict higher density values overall. These results highlight the importance of validating remote sensing electron density models with in situ observations and demonstrate the impact of different magnetic field inputs on space weather modeling. The improved agreement with ADAPT-GONG maps suggests that incorporating more dynamic and data-driven models can enhance the accuracy of electron density estimations, ultimately improving our understanding of solar wind structures and radio wave propagation in the heliosphere.

Probing accretion process and emission mechanism of X-ray pulsars in multi-wavelength

Date

2025-01-08

Speaker

Manoj Mandal

Venue

Online: https://imeet.vconsol.com/join/8880252012?be_auth=MjU0NzIy

Abstract

The timing and spectral studies have been carried out for several X-ray pulsars to probe the emission mechanism, accretion process, and spectral states. The timing and spectral properties evolve significantly above the critical luminosity. The accretion mode, beaming patterns, and emission mechanism evolve significantly above this luminosity. A significant evolution of temporal and spectral properties is observed during the state transition for X-ray pulsars, 1A 0535+262 and RX J0440.9+4431. A variable cyclotron line was detected from 1A 0535+26, and the magnetic field was estimated using the cyclotron line energy. The variation of the cyclotron line is probed. The significant evolution of line energy with luminosity was observed, which may be linked with the transition of state in the X-ray pulsars. The unstable burning of accreted material on the surface of neutron stars induces thermonuclear (Type-I) bursts. Thermonuclear bursts can be used to probe several properties of neutron stars. Multiple thermonuclear bursts were detected from MAXI J1816&#8722;195 and Aql X-1. The details of timing and spectral properties are studied during the X-ray bursts. The estimated mass accretion rate indicates the stable burning of hydrogen via a hot CNO cycle during the bursts.

A 3D Thermophysical model for Temperatures and Thermophysics at Prospective Sites on Mars

Date

2025-01-08

Speaker

K. Samadhanam Raju

Venue

online

Abstract

Existing thermal models of Mars, such as the KRC 1D model, lack the ability to account for complex heat transport processes, topographical variations, and environmental factors like dust storms and surface changes. This study addresses these gaps by developing a 3D thermophysical model that integrates lateral heat transport, accurate topography from MOLA DEM, and Martian-specific conditions, including its thin CO₂ atmosphere and thermal inertia. The model provides detailed insights into localized thermal variations at prospective landing sites, enhancing mission planning and advancing our understanding of Mars' thermal behavior and geological history.

Are humans now the dominant geological agent?

Date

2025-01-08

Speaker

Prof. Stephen Tooth Dept. Geography & Earth Sciences Aberystwyth University, Wales

Venue

Ground Floor Lecture Hall

Abstract

The Anthropocene is a term that has been proposed to account for the arguably ‘dominant’, ‘overriding’ or ‘overwhelming’ role of human activities in shaping the Earth’s geological record. Some academics have argued that we have now exited from the Holocene (the present interglacial time division) and entered a new geological age, one now defined by humanity’s profound influence on Earth’s atmospheric, biological, and earth surface processes. Although a subcommittee of the International Commission on Stratigraphy (ICS) has recently decided that the Anthropocene will not become an official epoch in Earth’s geological timeline, the term itself will endure because for many people it encapsulates the sense that humans are now a fundamental part of the Earth system and integral to its processes. The Anthropocene proposal has many philosophical, ethical, moral and practical implications, and will continue to generate lively academic debate across the natural sciences, social sciences, humanities and arts, while also providing scope for greater public engagement with environmental decision making. Adopting a geoscience perspective, this talk will outline the case for and against an Anthropocene, and outline ways in which we might compare landscape shaping by human activities and natural processes.

Anderson localization in QFT and hierarchies from nonlocality

Date

2025-01-07

Speaker

Dr. Ketan Patel, THEPH

Venue

Room no: 469 (Main Campus)

Abstract

It was shown in [1710.01354] that disordered local interactions in theory space can localize mass eigenstates (analogous to Anderson localization in disordered lattice) enabling exponentially hierarchical couplings in QFT. In this talk, I shall show that such theories can also produce multiple massless modes. Subsequently, deterministic nonlocality can give rise to hierarchies that are qualitatively distinct from the original proposal.

Loss Pathway of organic Carbon in the Himalayan Permafrost Region

Date

2025-01-07

Speaker

Rahul Kumar Agarwal

Venue

Ground Floor Lecture Hall

Abstract

Soil organic carbon (SOC) stored in permafrost regions represents a critical component of the global carbon cycle. Climate change significantly influences the distribution and dynamics of carbon across Earth's systems. It is widely believed that climate change is driving substantial carbon loss from high-latitude and high-altitude soils, including permafrost areas. However, the pathways through which soil organic matter is lost remain poorly understood, and the extent of older organic matter degradation, particularly in the high-altitude Himalayan permafrost regions, is not well quantified. To address this gap, we measured radiocarbon content in soil organic carbon, soil CO2, and soil CH4 across various depths of a peat profile located at approximately 4500 meters above mean sea level in the Sikkim Himalayas. In this talk I will discuss about the basics of mountain permafrost, radiocarbon dating of soil methane, and loss pathway of organic carbon in the permafrost region.

​Mathematical Framework for Dust Dynamics under Different Forces

Date

2025-01-03

Speaker

Ms. Aanchal Sahu

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Interplanetary Dust Particles (IDPs) are a fundamental constituent of the Solar System, originating from diverse sources such as the Asteroid Belt, Kuiper Belt, Oort Cloud, and comets. It manifests in phenomena like Zodiacal Light and Meteor showers. As IDPs migrate inward toward the Sun, their dynamics are governed by a combination of gravitational and non-gravitational forces, including Poynting-Robertson drag, solar radiation pressure, and solar wind drag, which induce perturbations in their orbital elements. In this seminar, I will discuss the mathematical framework for orbital perturbations and the governing force equations, derived from the principles of celestial mechanics. The variation in orbital elements due to the governing forces will be analyzed, along with the obtained results. In addition to this, the method for estimating the dust flux on planetary bodies will be explored, with a focus on insights derived from our research.

Probing the Cold Molecular Gas in Luminous Dusty Star-forming Galaxies at z~1-6

Date

2025-01-02

Speaker

Ms. Prachi Prajapati

Venue

Seminar Room No. 113, Thaltej

Abstract

The galaxies and star formation we see at present are attributed to a long history of galaxy formation and evolution. Reconstructing back in time the physical processes that led to the existing galaxies and explaining them in terms of different properties of the matter is one of the prime goals of the observational cosmology. In particular, studying the molecular gas content of high-redshift dusty star-forming galaxies (DSFGs) is of utmost importance for observationally confirming the galaxy formation and evolution theories. Observing the gas with low excitation leads to better mass estimates and also helps in deriving the gas and dust properties of these galaxies more accurately. Having a large and diverse sample of DSFGs for such a study plays an important role in setting up statistically significant trends within the DSFG population and in determining whether or not there are significant differences in the gas properties of DSFGs compared to other populations. This talk will be focused on the VLA large program to observe CO (1–0) in high-redshift DSFGs (0.8 < z < 6.5) for deriving insights on the cosmic star formation history.

Complete escape from localization on a hierarchical lattice: A Koch fractal with all states extended

Date

2025-01-02

Speaker

Sougata Biswas, Presidency University

Venue

Online--- https://imeet.vconsol.com/viewer/1718585506?be_auth=NTIwNzYy

Abstract

"An infinitely large Koch fractal is shown to be capable of sustaining only extended, Bloch-like eigenstates if certain parameters of the Hamiltonian describing the lattice are numerically correlated in a special way, and a magnetic flux of a special strength is trapped in every loop of the geometry. We describe the system within a tight-binding formalism and prescribe the desired correlation between the numerical values of the nearest-neighbor overlap integrals, along with a special value of the magnetic flux trapped in the triangular loops decorating the fractal. With such conditions, the lattice, despite the absence of translational order of any kind whatsoever, yields an absolutely continuous eigenvalue spectrum and becomes completely transparent to an incoming electron with any energy within the allowed band. The results are analytically exact. An in-depth numerical study of the inverse participation ratio and the two-terminal transmission coefficient corroborates our findings. Our conclusions remain valid for a large set of lattice models, built with the same structural units, but beyond the specific geometry of a Koch fractal, unraveling a subtle universality in a variety of such low-dimensional systems. Reference: S. Biswas and A. Chakrabarti, Physical Review B 108, 125430 (2023)."

Lunar Neutron Leakage Spectrum and its sensitivity to the presence of hydrogen in the lunar subsurface​

Date

2024-12-27

Speaker

Ms. Shipra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Moon's absence of a magnetic field and atmosphere exposes its surface to ionizing radiation, including solar wind, SEPs, and galactic cosmic rays. High-energy galactic cosmic rays interact with the lunar surface, generating fast neutrons through nuclear reactions. These fast neutrons are moderated by collisions with the nuclei of lunar soil and leak out, acting as messengers of the soil composition. Studying this neutron leakage spectrum can reveal important information about the Moon’s soil composition and near-surface hydrogen abundance. In this seminar, I will discuss the production and moderation processes of neutrons inside the lunar surface.

Observational determination of magnetic helicity and energy flux in the solar active regions.

Date

2024-12-27

Speaker

Mr. Dinesh Mishra

Venue

USO Seminar Hall

Abstract

Magnetic helicity measures the degree of twisting of magnetic flux tubes, the shearing of magnetic arcades, and the interlinking of magnetic flux tubes. It plays an essential role in understanding the evolution of magnetic fields in the solar active regions and the triggering mechanism of solar transients that take place in the solar atmosphere, viz., flares and CMEs. In this talk, I will discuss about the estimation of magnetic helicity and the associated energy flux in the solar active regions using the observed photospheric vector magnetic fields and their importance.

Introduction to Solar Flares and Magnetic Reconnection.

Date

2024-12-26

Speaker

Ms. Simrat Kaur

Venue

USO Seminar Hall

Abstract

Solar flares are sudden explosive events on the Sun that release energy through heating, electromagnetic radiation, and the acceleration of charged particles. These events are believed to be the manifestations of the magnetic reconnection process and can release energy ranging from 10^23 erg to 10^32 erg. In this seminar, I will discuss Solar flares and how they are connected to magnetic reconnection.

The Journey of Star Formation: From Collapsing Cloud to Accreting Protostar

Date

2024-12-26

Speaker

Kushagra Srivastav

Venue

Seminar Room No. 113, Thaltej

Abstract

Star formation is a fundamental and vital process of molecular cloud evolution and the creation of stellar systems. Stars are born within the dense, compact, and low-temperature regions of molecular clouds called cores. These dense cores are the sites that eventually lead to the formation of a protostar, surrounded by a protoplanetary disc and an infalling envelope. Understanding the various stages, from the collapsing cores to the formation and growth of a protostar, requires understanding the physical and dynamic processes involved. In this talk, I will discuss the various stages of star formation and the role of different physical processes involved and also touch upon the evolution of a protoplanetary disk and the accretion from the disk to the star.

Solar Flares: Multi-wavelength Observations

Date

2024-12-24

Speaker

Mr. Vishwa Vijay Singh

Venue

USO Seminar Hall

Abstract

Solar flares are among the most energetic events in the solar system, characterized by the sudden release of magnetic energy stored in the Sun’s corona. These phenomena emit radiation across the entire electromagnetic spectrum, from radio to γ-rays. Multi-wavelength observations provide a comprehensive understanding of the physical processes driving solar flares, including energy release, particle acceleration, plasma heating, and large-scale coronal restructuring. In this seminar, I will highlight the complementary nature of multi-wavelength observations in understanding the temporal and spatial evolution of solar flares. Additionally, we will discuss the role of magnetic reconnection and its association with large-scale phenomena such as coronal mass ejections (CMEs).

Speleothem Paleoclimatology: Insights from Clumped and Triple Oxygen Isotopes

Date

2024-12-24

Speaker

Ms. Aishwarya Singh

Venue

Ground Floor Lecture Hall

Abstract

A multitude of creditable terrestrial paleoclimate reconstructions have been done using oxygen isotope ratios in speleothems based on the temperature dependency of the carbonate-water isotope exchange equilibrium. However, these interpretations remain inadequate due to improper constraints on drip-water isotopic compositions and possible kinetic isotopic effects. Moreover, the variations in the oxygen isotopes of speleothems are affected by both temperature and precipitation, making it challenging to estimate their individual contributions. Clumped isotope thermometry, based on the abundance of 13C-18O bonds, is capable of constraining the growth temperature of carbonates independent of the isotopic composition of drip water. The clumped-derived temperature can be combined with oxygen isotopes to constrain the paleo-temperature and paleo-precipitation values, subject to the maintenance of thermodynamic equilibrium. To validate the latter, triple oxygen isotopes will be analysed alongside clumped isotopes in modern speleothems. Triple oxygen isotopes also present a potential strategy to decipher the various fractionation processes from the moisture source, en route to its final sink. In this seminar, I will discuss how these emerging techniques can be used to significantly improve our understanding of the paleoclimate beyond what was possible with the conventional methods.

Rim-breached Craters: Insights into fluvial activities on Mars

Date

2024-12-20

Speaker

Rishav Sahoo

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

On Mars, there are a substantial number of craters whose rims are breached due to external activity like catastrophic outflow channels, river channels, and valley networks. These rim-breached craters are the potential targets till date for the Mars rover mission due to their enriched fluvial origin deposits. The dimensions of these breaches—specifically breach width and breach height—are directly related to the volume of water that interacted with the crater rims over time. Understanding these breach parameters is essential for estimating the volume of water involved, the rate of discharge, and the velocity of water flow throughout Mars's geological history. This study concentrates on the rim-breached craters located in the Chryse Planitia region, which features various types of fluvial valley networks, particularly those associated with the Valles Marineris region on Mars.

Properties of Sunspot Umbral Dots

Date

2024-12-20

Speaker

Mr. Amit Chaturvedi

Venue

USO Seminar Hall

Abstract

Umbral Dots (UDs) are small, bright structures seen in the dark umbral core of pores and sunspots. They represent convective intrusions in the highly magnetized surroundings of the sunspot's umbra. In this talk, I will review the photometric, kinematic, and magnetic properties of UDs from high resolution ground- and space-based observations.

Dynamics of Solar Corona Heliospheric Interaction

Date

2024-12-19

Speaker

Ritik Dalakoti

Venue

Room No. 113, Thaltej

Abstract

The lower solar corona exhibits significant dynamic activity across various scales, with magnetic features continuously forming and disappearing on the Sun's surface. Understanding the relationship between these features and the heliosphere is crucial for understanding the heliosphere and predicting the flow of plasma within it. This knowledge is essential for forecasting space weather accurately. In this study, we investigate an M-class solar flare from which plasma eventually propagated into the heliosphere. We examine the evolution of First Ionization Potential (FIP) elements during the flare using the soft X-ray spectrum from the Solar X-ray Monitor aboard Chandrayaan-2. Additionally, we analyse in situ particle data to determine whether the evolution of FIP elements can be observed at 1 AU or other heliospheric locations.

Exploring small-scale transient brightenings in the context of solar atmospheric heating

Date

2024-12-19

Speaker

Mr. Hasil Dixit

Venue

USO Seminar Hall

Abstract

Effective theories at finite temperature

Date

2024-12-19

Speaker

Prof. Subhendra Mohanty, IIT Kanpur

Venue

Room no: 469 (Main Campus)

Abstract

Effective theories offer an economical way to test the predictions of diverse UV complete theories in low energy experiments. The finite temperature formulation of effective theories is needed for applications in cosmology and collider experiments in phase transitions, quark gluon plasma, Casimir effect etc. I will discuss a way to formulate effective theories at finite temperature using the Heat Kernel Method which involves the calculation of finite temperature corrections to the Wilson coefficients. I will illustrate the results with a calculation of Coleman-Weinberg potential for the Higgs-Effective field theory and apply it in testing the nature of phase transition from different extensions of the standard model. Of particular interest is the emergence of Polyakov loops as a parameter which has applications in phase transitions and spin-systems in condensed matter.

Terrestrial Recycling and its linkages to Meteorology: Insights from stable water isotopes in vapor in conjunction with Machine Learning, at a high-altitude site in western India

Date

2024-12-17

Speaker

Akash Ganguly

Venue

Ground Floor Lecture Hall

Abstract

The implications of a warming climate have raised awareness towards potential hydrological challenges, with a conspicuous rise in both frequencies, as well as intensity of extreme events. Moisture recycling, accounting for ~67 (40) % of the net terrestrially sourced precipitation globally (India), is a vital component of the water cycle. The recycled moisture is primarily contributed via two major sources- i) direct evaporation from surface reservoirs ii) transpiration from dense forests. However, delineating their relative contributions has proved challenging using conventional tools. In this study, we leverage stable water isotopes in vapor from the highest point in western India to track moisture transport, and constrain the role played by the regional meteorology in governing terrestrial recycling during pre-monsoon. The study location (Gurushikhar, Mt. Abu) perfectly aligns with our objective, with it being a natural bio-diversity hotspot, with ~288 sq. km. of densely forested terrain, and very low levels of air pollution. A novel statistical-machine learning framework is developed to quantitatively infer the non-linear relationships, governing the high-dimensional coupled land-atmospheric system. Here, we find 1) A strong inverse relationship between wind-speed, and deuterium excess, suggesting increased role of kinetic processes. 2) Dominant role of valley recycling, with ~30-40 % contribution from transpiration alone. 3) Elevated levels of tropospheric ozone (> 65 ppbv.) suppressing transpiration rates, resulting in up to 2 ‰ depletion in δ18O. 4) Possible signs of upper atmospheric coupling via waves, extending to ~ 10 km (above msl) 5) Development of a robust, accurate ML model with mae ~ 3.50 ‰ in δ18O, using only meteorological inputs. This study highlights the benefit in using stable water isotopes in vapor, since they can be leveraged to better understand linkages between terrestrial recycling, and regional hydro-meteorology. This brings to light the important role played by the dense vegetation cover around Mt. Abu, acting as nature’s pump and enhancing terrestrial recycling. This is of even more significance in the tropics, given the rapid loss of wetlands, and forest cover in the developing countries located in the region.

Solving the strong CP puzzle through Radiative mass mechanism

Date

2024-12-16

Speaker

Gurucharan Mohanta, SRF

Venue

Room no: 469 (Main Campus)

Abstract

I will briefly outline the radiative mechanism for fermion mass generation and focus on how it can address the strong CP problem. To do this, the mechanism is implemented within a parity-invariant Left-Right symmetric framework. In this setup, loop-induced fermion masses arise from corrections involving a new flavor-non-universal gauge boson and heavy fermions. The required non-universal U(1) symmetry for the mechanism is an all-fermion version of the $L_\mu - L_\tau $ symmetry. The minimal model predicts that the mass of the U(1) gauge boson and the scale of right-handed sector breaking are of the same order. This leads to a strong CP phase of the order of $10^{-14} $.

Improving Solar Wind Forecasting Model Over the Phase of Solar Cycle - Source Surface Height Optimization and Magnetogram Impact

Date

2024-12-16

Speaker

Mr. Sandeep Kumar

Venue

USO Seminar Hall

Abstract

The operational solar wind velocity prediction models used by the community are based on the Potential Field Source Surface (PFSS) model of the magnetic field. The output of PFSS serves as input in the heliospheric models to provide solar wind velocity predictions at L1. Previous studies in the context of the prediction of open magnetic flux observed at L1 have suggested different source surface heights ($R_{ss}$) in the PFSS model at different phases of the solar cycle (SC). We investigate the effects and necessity of optimizing the $R_{ss}$ in the PFSS model in the context of its use in the popular Wang Sheeley and Arge (WSA) model for solar wind velocity prediction. We used Heliospheric Upwind Extrapolation (HUX) to extrapolate solar wind velocity in the heliosphere. We performed a study of 16 Carrington Rotations (CR) at different phases of the SC24 and SC25, using different types of magnetograms and WSA model parameters. We combine the coronal models (PFSS+WSA) with the heliospheric model (HUX) to predict solar wind velocity at L1 in our framework, i.e., PFSS+WSA+HUX. Our study suggests using a higher $R_{ss}$ ($3.0$ $R_\odot$) compared to the conventional $R_{ss}$ (2.5 $R_\odot$) near the solar minimum, resulting in an increase in the average performance of the framework. We found that the improved performance of the framework by 2 times with zero-point corrected maps, as compared to the standard full Carrington maps, can be attributed to its capability to capture the global magnetic field. This was also confirmed by comparing the extrapolated global magnetic field structures with the large-scale corona observed in the extended field of view of the PROBA2/SWAP images.

Vacuum Ultraviolet Photolysis of Clathrate Hydrates under Cometary Conditions

Date

2024-12-13

Speaker

Gaurav Vishwakarma

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Clathrate hydrates (CHs), naturally occurring in high-pressure terrestrial environments, have also been identified in interstellar conditions, where they are thought to play a significant role in the chemistry of icy bodies. Despite their importance in astrochemical models, the interactions of CHs with ultraviolet (UV) radiation remain poorly understood. In this study, we employed reflection absorption infrared spectroscopy to explore UV photolysis and subsequent thermal evolution of CHs under ultrahigh vacuum (~10⁻¹⁰ mbar) and cryogenic temperatures. Our findings demonstrate that CHs serve as molecular reservoirs, preserving volatile species while acting as microreactors that facilitate unique chemical transformations. Notably, UV-photolyzed CHs exhibited a remarkable ability to nucleate new CHs of simple molecules upon warming—a phenomenon not observed in amorphous ice analogs. These results emphasize the distinctive role of CHs in shaping photochemical pathways and retaining photoproducts under simulated interstellar conditions. I will discuss these findings in detail during my presentation, highlighting their implications for both laboratory astrochemistry and our understanding of icy environments in space.

Uncovering the hidden physical structures and protostellar activities in the Low-Metallicity S284-RE region: results from ALMA and JWST

Date

2024-12-12

Speaker

Omkar Jadhav

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Over the past decade, Spitzer and Herschel observations have provided invaluable opportunities to explore key structures in star-forming regions, such as bubbles and filaments. With the advent of the James Webb Space Telescope (JWST) and the Atacama Large Millimeter/submillimeter Array (ALMA), researchers have access to a powerful multi-wavelength approach, which can be used to investigate the dust and gas structures around embedded protostars in exceptional detail and to study distant star-forming sites. We present an observational study of the S284-RE region (d ~5.0 kpc), a low-metallicity area associated with the extended S284 HII region. The S284 region is characterized by features such as filaments, pillars, and globules, which are hallmarks of star-forming regions shaped by stellar feedback. Multi-scale and multi-wavelength datasets are used to explore the underlying physical structures and protostellar activities in this site. In this talk, I will provide a detailed overview of our findings and their implications for understanding the physical processes driving star formation in S284-RE.

A leisurely walk through few exotic manifestation of interacting spin systems

Date

2024-12-11

Speaker

Dr. Saptarshi Mandal

Venue

Room no: 469 (Main Campus)

Abstract

In the talk we discuss some of the fascinating aspects of frustrated magnetism in a few systems of our interest. We begin with a discussion of the origin of frustration in model systems through examples of geometric and exchange effects. The manifestation of frustration giving degenerate ground states, order-disorder phenomena through quantum fluctuations are explained in the Hollandite lattice system. Next the ground state of varieties of systems following ice rules are explained and how emergent electrodynamics is obtained are outlined. Finally we introduce Kitaev model and explain the effect of frustration and give a pedagogical exposition to abelian and non-abelian anyons or Majorana fermions obtained in this system.

Estimation of fine particulate matter and aerosol acidity at Ranchi, India

Date

2024-12-10

Speaker

Dr. Abisheg Dhandapani

Venue

Ground Floor Lecture Hall

Abstract

The annual PM2.5 concentration was 67 ± 46 μg m-3 at Mesra, Ranchi, varying seasonally. There was a significant underestimation in MERRA-2-derived PM2.5, and machine learning techniques were used to overcome the challenge. Further, water-soluble inorganic ions accounted for 50.5% of PM2.5, and the annual mean pH estimated using ISORROPIA was 1.97 ± 0.8 units. Secondary aerosols formation (45%) and a combination of coal combustion and dust sources (10%) were the primary sources of PM2.5 identified using PCA.

Advances in Satellite Radar Imaging

Date

2024-12-06

Speaker

Rajiv Ranjan Bharti

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Recently, IIRS Dehradun conducted the Structured Training Program (STP). The theme of the STP was "Advances in Satellite Radar Imaging". 28 Scientists/Engineers from ISRO/DOS Centers participated in the program. The programme covered the basics of radar remote sensing and its applications like natural resources management, agriculture, and infrastructure planning, disaster management and planetary exploration. This seminar will cover a brief discussion based on the lectures given by various faculty members in the STP.

An X-ray Perspective on Multi-scale Solar Flares: Spectroscopy to Polarimetry

Date

2024-12-06

Speaker

Dr. Mithun Neelakandan P S

Venue

USO Seminar Hall

Abstract

Solar flares have a wide range of intensity scales ranging from large X-class flares to microflares to hypothesized nanoflares that may be responsible for coronal heating. Investigations of multi-scale solar flares, from large flares to the smallest microflares, are key to the missing pieces in our understanding of the flaring process and coronal heating. As the flaring plasma and accelerated electrons emit profusely in soft and hard X-rays, X-ray spectroscopic observations offer the most direct diagnostics of the thermal and non-thermal particle populations in flares and, thus, insights into the energy release mechanisms in flares. Solar X-ray Monitor (XSM) onboard the Chandrayaan-2 mission provides disk-integrated X-ray spectral measurements of the Sun in the energy range of 1-15 keV, with a high dynamic range to observe sub-A class micro flares to large X-class flares. XSM has recently completed five years of continuous solar observations and in this talk I will highlight some of the major results using XSM observations on various aspects of multi-scale solar flares. I will also introduce other recently operational solar soft X-ray spectrometers on other missions and on the advantages of simultaneous analysis of soft X-ray spectra with the hard X-ray spectra from instruments such as Solar Orbiter STIX and Aditya L-1 HEL1OS. Going beyond spectroscopy, I will also discuss the potential of X-ray polarimetric observations of solar flares and our efforts towards a small satellite experiment, which would also be a pathfinder to an X-ray astronomy mission.

Surface Tension of a Topological Phase

Date

2024-12-06

Speaker

Dr. Adhip Agarwala

Venue

Room no: 469 (Main Campus)

Abstract

Metastable phases, in general, are unstable to nucleating droplets of the order defining the global free energy minima. However, whether such a droplet grows or shrinks relies on a competition between the surface tension and bulk energy density. We study the role of coupling a topological fermionic field to a scalar field undergoing such nucleation processes. We find that existence of nontrivial fermionic boundary modes on the nucleating droplets leads to substantial quantum corrections to the surface tension thereby modifying the size of the critical nucleus beyond which unrestricted droplet growth happens. To illustrate the phenomena we devise a minimal model of fermions in a Chern insulating system coupled to a classical Ising field in two spatial dimensions. Using a combination of analytic and numerical methods we conclusively show that topological phases can lead to characteristic quantum surface tension. In this talk I will try to motivate some of these questions, and provide a general overview of quantum condensed matter landscape.

Studying solar flares with the X-ray telescope STIX on Solar Orbiter

Date

2024-12-05

Speaker

Dr. Alexander Warmuth

Venue

USO Seminar Hall

Abstract

Of the six remote-sensing instruments aboard ESA's Solar Orbiter spacecraft, the Spectrometer/Telescope for Imaging X-rays (STIX) is the one dedicated to the study of solar flares. It performs X-ray imaging spectroscopy in the hard X-ray regime, which provides key physical diagnostics on both the hot thermal plasma as well as on the accelerated energetic electrons. During its operation since launch in 2020, STIX has detected over 56,000 solar flares. I will discuss how the STIX data are used to study energy release and particle acceleration in solar flares. In particular, I will focus on studies that use STIX jointly with other observational assets, such as the other remote-sensing instruments on Solar Orbiter, various instruments on other spacecraft, and in-situ particle detectors.

Unveiling the mechanism behind sign changes in the thermopower and Hall coefficient of strained Sr2RuO4

Date

2024-12-04

Speaker

Dr. Sudeep K. Ghosh, IIT Kanpur

Venue

Room no: 469 (Main Campus)

Abstract

Sr2RuO4 is a fascinating material in condensed matter physics, celebrated for its unconventional superconductivity and intricate electronic structure. A particularly intriguing aspect is its strain-induced Lifshitz transition, which profoundly influences transport properties. Notable among these effects are the sign changes observed in the thermopower and Hall coefficient under strain, a phenomenon that remains not fully understood. In this talk, I will explore these transport properties using the semiclassical Boltzmann transport formalism, examining both unstrained and strained (uniaxial and c-axis) systems. I will demonstrate that the sign changes are driven by the Van Hove singularity, which emerges as a direct consequence of the Lifshitz transition, offering deeper insights into the electronic structure and transport behavior of Sr2RuO4.

Major ion and trace element geochemistry of the Mahi River

Date

2024-12-03

Speaker

Dr. Shailja Singh

Venue

Ground Floor Lecture hall

Abstract

River Mahi drains through semi-arid regions of Western India and is the third-major river draining into the Arabian Sea. This work presents an extensive dataset on the major ion and trace element (TE) geochemistry of the Mahi River which forms a part of our continued geochemical investigation on the role of the medium-sized river system in transporting dissolved loads to the Arabian Sea. The major ion data was used to get detailed insights into sources of major ions and their relative contributions by a forward model; seasonal, spatial, and inter-annual variability of these ions, weathering rates, and associated CO2 drawdown of the basin. Likewise, the trace element data was analyzed to identify the role of natural and anthropogenic sources in contributing to TE distribution and understand their spatial and temporal variability. With TEs' obvious link to water quality issues and human health, this work also attempted predictive modeling of pollution indices by Machine Learning models. In this talk, the important results borne out of the work will be discussed.

Introduction to High-Energy Neutrino Astrophysics

Date

2024-12-02

Speaker

Dr. Bhupal Dev, Washington University, USA

Venue

Room no: 469 (Main Campus)

Abstract

We will provide a pedagogical introduction to High-Energy Neutrino Astrophysics and the emerging field of Multimessenger Neutrino Astronomy. We will discuss how the high-energy neutrinos are produced, propagate and are detected and what they can tell us about the origins of cosmic rays, dark matter, and other fundamental puzzles of the Universe.

Fast Radio Bursts, a recent discovery in the field of Transients

Date

2024-11-29

Speaker

Shruti Bhatporia

Venue

USO Seminar Hall

Abstract

Fast radio bursts (FRBs) are high-energy transient signals of millisecond duration detected by radio telescopes around the world. The origins of such FRBs are unknown. Therefore multiple theoretical models have been put forward to explain the phenomena. The frequency distribution of energy, duration, and waiting time for solar radio bursts is similar to that of FRBs. There is a correlation between the X-ray and radio luminosity of solar radio bursts, which suggests that the energetic electrons that cause radio emissions and X-ray flares have a common origin. In this talk, I will give an introduction to fast radio bursts and elaborate on ongoing multi-wavelength observation efforts.

Collider fingerprints of freeze-in dark matter

Date

2024-11-29

Speaker

Dr. Anupam Ghosh, PDF, PRL

Venue

Room no: 469 (Main Campus)

Abstract

We examine a simple dark sector extension where the observed dark matter (DM) abundance arises from a freeze-in process through the decay of heavy vector-like quarks into a scalar dark matter candidate. The detection prospects of such DM are challenging due to the feeble nature of the interactions, but these vector-like quarks can be produced copiously at the LHC, where they decay to Standard Model quarks along with DM. Depending on the decay rate, this scenario is typically probed through long-lived particle or displaced vertex signatures, assuming a radiation-dominated background. An alternative hypothesis suggests that the Universe may have experienced a rapid expansion phase instead of the standard radiation-dominated one during freeze-in. This would significantly alter the dark matter phenomenology, requiring a substantial increase in the interaction rate to match the observed relic density, resulting in the rapid decay of the parent particle. As a result, much of the parameter space for this scenario is beyond the reach of traditional long-lived particle and displaced vertex searches. Due to this non-standard cosmic evolution, existing constraints do not cover the expanded dark matter parameter space. We propose a complementary search strategy to explore this scenario, offering additional limits alongside searches for long-lived particles and displaced vertices. In our search, we investigate the FIMP dark matter model at the LHC using boosted fatjets and significant missing transverse momentum. To improve precision, we include one-loop QCD corrections for LHC production processes and employ a boosted decision tree multivariate analysis, leveraging jet substructure variables to explore a vast parameter space for this minimally extended FIMP dark matter model at the 14 TeV LHC.

TOI-6038 A b: Discovery of a sub-Saturn orbiting a late F-type star in a wide binary system

Date

2024-11-28

Speaker

Sanjay Baliwal

Venue

Room No. 113/114, Thaltej

Abstract

The discovery of exoplanets has revealed numerous planetary populations with no analogs in the Solar System. Among these, sub-Saturn exoplanets, larger than Neptune but smaller than Saturn and in close orbits around their host stars, represent a particularly intriguing class. Sub-Saturns are often described as failed gas giants, possessing equally massive cores but significantly smaller total masses due to their much smaller accreted envelopes. In this talk, I will discuss our recent discovery of a sub-Saturn TOI-6038 A b using PARAS-2 spectroscopic observations. TOI-6038 A b is a relatively dense sub-Saturn with a mass of approx 79 Earth masses and a size of about 6.4 Earth radii, orbiting a bright, metal-rich late F-type star in a nearly circular orbit with a period of about 5.83 days. The system also contains a wide-orbit binary companion, TOI-6038 B, which is an early K-type star at a projected separation of 3217 AU. Internal structure modeling indicates that about 74% of the planet’s mass is made up of rocky materials forming the core, with the rest consisting of a low-density H/He envelope. TOI-6038 A b lies in the transition zone between the Neptunian ridge and savanna, making it a key system for understanding the formation and evolution of close-in sub-Saturns. While its high density is consistent with planets shaped by high-eccentricity tidal migration, the exact migration pathway remains unclear. The planet’s bright host star makes it a promising candidate for future atmospheric escape and orbital architecture observations, which will help us better understand its overall evolution.

Neutrinos: Dirac or Majorana

Date

2024-11-26

Speaker

Dr. Bhupal Dev, Washington University, USA

Venue

Room no: 469 (Main Campus)

Abstract

Whether neutrinos are Dirac or Majorana particles is an open question in fundamental physics. Theoretically, it is also possible that neutrinos are pseudo-Dirac, which are fundamentally Majorana fermions, but essentially act like Dirac fermions in most experimental settings, due to extremely small active-sterile mass splitting. Such small values of mass splitting can be accessed via active-sterile oscillations over an astrophysical baseline. We use the recent multi-messenger observations of high-energy neutrino sources to probe hitherto unexplored values of active-sterile mass splitting, which improve the reach of terrestrial experiments by more than a billion.

Understanding the Ocean Conditions during the Neoproterozoic: Depositional Environment, Primary Productivity and Hydrographic Setting of Vindhyan Basin

Date

2024-11-26

Speaker

Mr. Deependra Singh

Venue

Ground Floor Lecture hall

Abstract

Neoproterozoic Ocean is considered as a profound interval of global environment changes in the geological history. To asses the redox history and primary productivity in the Neoproterozoic ocean is crucial for better understanding of past climate and the changes happened that time. In this talk, I will discuss about utilization of various trace elements and Mo isotopic composition as proxy to understand the paleo environmental conditions of Neoproterozoic upper Vindhyan basin.

PROBA-3 mission

Date

2024-11-25

Speaker

Dr. Marek Jerzy Stęślicki

Venue

USO Seminar Hall

Abstract

Understanding Solar Eruptions: Ongoing and Future Research Programs at Space Research Centre of Polish Academy of Sciences.

Date

2024-11-25

Speaker

Dr. Tomasz Maciej Mrozek

Venue

USO Seminar Hall

Abstract

Solar Physics Division, Space Research Centre of the Polish Academy of Sciences aims to observe and interpret solar X-rays. The group performed the first Polish space experiment (54 years ago) resulting in X-ray images obtained using several filters. SPD's increasing heritage led us to participate in the STIX experiment onboard the Solar Orbiter mission. The STIX's data analysis and interpretation is now our main activity. Apart from this, we are involved in CubiXSS experiment (NASA-lead) and MIRORES (all-Polish). During my seminar, I will shortly present the team, our experience, achievements and future ideas that we hope to realize.

Probing the Physics of Radiation and Particles Emitted During Energetically-Rich Solar Flares

Date

2024-11-21

Speaker

Dr. Arun Kumar Awasthi

Venue

USO Seminar Hall

Abstract

Solar flares are one of the earliest observational signatures of solar eruptions. Although the X-class flares are the largest in intensity class, weaker (micro/nano) flares are more frequently occurring. Therefore, they are not only a suitable candidate for coronal heating, but their investigation may also provide crucial insights into the origin of particle emission from the Sun. By reconciling multi-wavelength observations, the standard flare energy release scheme puts forth the physical mechanism responsible for the radiation and particle emission during flares. However, this scheme is often challenged by the observations, particularly during weak flares that remained less investigated in the past owing to observational limitations. Therefore, it is yet to be understood if the weak flares are just a scaled-down version of large flares in the sense of physical processes. In this context, I will provide an overview of the role of weak flares as unique tracers of pre-eruptive plasma and magnetic field environment from the insights gained from our research investigations. I will also provide an overview of our future plans associating the physics of solar flares with the initiation mechanism of the coronal mass ejections with an emphasis on combining the observations from the ADITYA-L1 and the Solar orbiter missions.

Holocene climate reconstruction from the southern Arabia: A tale of monsoons, humans, and lakes

Date

2024-11-19

Speaker

Mr. Shah Parth

Venue

Ground Floor Lecture hall

Abstract

The Arabian Desert is considered climatic sensitive zone which is susceptible to changes subtle global atmospheric circulation. The unique geographical location of this region can provide an excellent opportunity to understand the interactions between the monsoons, zonal migrations of the Inter-Tropical Convergence Zone (ITCZ) and regional environmental change. Thus, this project aims to provide the lacking high-resolution information on climate variability in the southern margins of the Arabian Desert through multiproxy approach carried out on a sediment core retrieved from Lake Karif Shawran and paleolake Gayal el Bazal, southern Arabian Desert. The multi-proxy approach includes granulometry analysis, elemental geochemistry, TOC/TIC, ostracod, biomarkers (n-alkanes, Pr/Ph, PAHs, Coprostanol, Stigmastanol and compound specific isotopes). Changes in the lithology and related measured proxies clearly indicate alternating wet and dry periods throughout the last ~4400 years. The wet climatic episodes coincide with globally recognized climate events including the Medieval Climate Anomaly (MCA), and the Roman Warming Period (RWP), whereas the dry intervals occurred during the Little Ice Age (LIA), Late Antique Little Ice Age (LALIA), and the ‘4.2k event’. Overall, we have reconstructed the late Holocene in the southern Arabian desert and discussed the impact of climate on the regional environment and lake system. Moreover, estimating the impact of climate on humans in the region by differentiating climatic signals from anthropogenic signals. The study provides key insights into the main driving forcing behind hydroclimatic changes in the region and sheds light on the role of the ITCZ vis-à-vis monsoonal dynamics. Additionally, it lays the foundation for better understanding long-term seasonal predictions for Southern Arabia.

Active Galactic Nuclei - An Overview

Date

2024-11-14

Speaker

Priyadarshee P. Dash

Venue

Seminar Room #113 (Thaltej Campus)

Abstract

Active Galactic Nuclei (AGN) are among the most energetic and luminous astronomical sources in the Universe. With bolometric luminosities reaching up to Lbol = 1048 erg s&#8722;1 (or 1015 L&#8857;), the AGNs emit across the entire range of the electromagnetic spectrum. The central source in an AGN is thought to be a supermassive black hole actively accreting nearby matter through an accretion disk, releasing substantial energy in the process. In this talk, I will provide an overview of various components of an AGN that account for its distinctive features across different regions of the electromagnetic spectrum. Emphasis is placed on the X-ray spectrum of the AGN, which offers crucial insights into the energetic processes close to the central engine. Finally, I will discuss the Unified Model of AGNs, which explains how diverse astronomical objects - such as Seyfert galaxies, quasars, radio galaxies - fit under the overarching category of AGN, despite differing in their observational characteristics.

Formation of homologous blowout jets and their large-scale consequences

Date

2024-11-14

Speaker

Dr. Binal Patel

Venue

USO Seminar Hall

Abstract

Coronal jets are identified as transient coronal-temperature ejections from near the solar surface into the corona. A particular type of coronal jet, known as a blowout jet, has gained significant attention in recognizing the physical mechanism governing the jet-coronal mass ejection (CME) relationship. In this talk, I will discuss the formation of four CMEs originating from homologous blowout jets. All of the blowout jets originated from NOAA Active Region (AR) 11515 on 2012 July 2, within a time interval of 14 hr. All of the CMEs were wide (angular widths between 95–150 deg), and propagated with speeds ranging between 300 and 500 km/s in LASCO coronagraph images. Observations at various EUV wavelengths in Solar Dynamics Observatory/Atmospheric Imaging Assembly images reveal that in all the cases, the source region of the jets lies at the boundary of the leading part of AR 11515 that hosts a small filament before each event. Coronal magnetic field modeling based on nonlinear force-free extrapolations indicates that in each case, the filament is contained inside of a magnetic flux rope that remains constrained by overlying compact loops. The southern footpoint of each filament is rooted in the negative polarity region where the eruption onsets occur. This negative polarity region undergoes continuous flux changes, including emergence and cancellation with opposite polarity in the vicinity of the flux rope, and the EUV images reveal brightening episodes near the filament’s southeastern footpoint before each eruption. Therefore, these flux changes are likely the cause of the subsequent eruptions. These four homologous eruptions originate near adjacent feet of two large-scale loop systems connecting from that positive polarity part of the AR to two remote negative polarity regions, and result in large-scale consequences in the solar corona.

The Mesoarchean Gabbro anorthosite suite: a window to understand the Mesoarchean crustal formation.

Date

2024-11-12

Speaker

Ms. Mudita Tater

Venue

Ground Floor Lecture hall

Abstract

Gabbro anorthosite rocks preserved in Archean terranes give an important view of early earth geodynamic processes. One such Gabbro anorthositic complex is also reported from the Singhbhum craton. These Mesoarchean rocks preserves the crustal record from Hadean to Archean. In this talk, I will summarize the work done till date on these Mayurbanj Gabbro anorthosite rocks and upbring the current controversies or current research gaps within this area. I will also talk about the potential lunar analogue site. Whether the present gabbro anorthosite complex can be established as potential lunar analogue site.

Implications of Residual modular symmetries on neutrino masses and mixing

Date

2024-11-11

Speaker

Dr. Monal Kashav, PDF, THEPH

Venue

Room no: 469 (Main Campus)

Abstract

"This talk explores the implications of modular invariance for neutrino mass matrices at the self-dual point τ=i. Assuming both exact self-duality and modular form for the neutrino Yukawa couplings provides some new insights into neutrino mass and mixing patterns. "

Investigation of the source of whistler waves observed near Venus

Date

2024-11-08

Speaker

Aarti Yadav

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Whistler waves are electromagnetic plasma waves which are frequently observed near Venus. On Venus, atmospheric lightning is considered as a source of whistler wave generation. However, a recent observation made by Parker Solar Probe during its 4th Venus flyby, detected whistler waves in the magnetotail region. After further analysis it was found that the origin of these waves is inconsistent with planetary sources. Investigation of the new source is necessary to add the valuable information about whistler waves, its generation process and the planetary medium through which they are propagating. We will discuss the potential new source which can be responsible for the generation of these waves. The main focus will be the analysis method which will be used in the investigation of the source of whistler wave generation in the magnetotail region of Venus. After that we'll discuss the initial results obtained by using the analysis method.

Ultraviolet Observations of the Martian Upper Atmosphere

Date

2024-10-25

Speaker

Dr. Krishnaprasad Chirakkil, Research Scientist Laboratory for Atmospheric and Space Physics, University of Colorado, Boulder, USA.

Venue

Online Meeting

Abstract

Ultraviolet emissions from planetary atmospheres are valuable for studying the composition and energetics of the upper atmosphere. In this seminar, I will discuss observations from the Emirates Mars Mission (EMM) / Emirates Mars Ultraviolet Spectrometer (EMUS), which have enabled us to study the thermosphere, exosphere, and auroral processes at Mars in unprecedented detail. EMUS is a far ultraviolet (FUV) spectrograph operating in the wavelength range of approximately ~100–170 nm. Its high sensitivity and the unique orbit of EMM allow for synoptic disk imaging and profiling of the tenuous oxygen corona, which is otherwise difficult to observe. The oxygen emission line at 130.4 nm is a prominent emission feature observed both on the dayside and the nightside during discrete auroras. We utilized this emission to construct over 500 oxygen corona profiles, ranging from exobase altitude up to several Martian radii, across all seasons and over two Martian years. Our analysis revealed that the OI 130.4 nm emission is highly correlated with solar irradiance and the Sun–Mars distance, exhibiting short-term variability consistent with the solar rotation period (~27 days) and long-term variability associated with the progression of the solar cycle. Comparison between Mars Years 36 and 37 showed interannual variability, with enhanced emission intensities during MY 37 due to the rise of Solar Cycle 25. These observations indicate a highly variable oxygen corona, which has significant implications for understanding the photochemical escape of atomic oxygen from Mars. Furthermore, our comprehensive study of nightside discrete auroras revealed distinct patterns in auroral occurrence. Aurora activity is higher in regions with open magnetic topology, occurring more frequently near the terminator and predominantly on the dusk side of the night hemisphere. Aurora occurrence exhibits a seasonal dependence, peaking near perihelion and increasing with solar activity. The brightest auroral emissions were detected during space weather events such as coronal mass ejections and stream interaction regions. These findings enhance our understanding of where and when Martian auroras occur, offering insights into the planet's magnetic environment and its interaction with the heliosphere. Overall, EMUS observations provide new insights into the variability of the Martian oxygen corona and auroral phenomena, contributing to our understanding of Mars' atmospheric escape processes and its interaction with the solar wind.

Enhancing Localization of Daksha-GRBs using Coded Mask Imaging Technique

Date

2024-10-24

Speaker

Mr. Ashish Kumar Mandal

Venue

Seminar Room #113 (Thaltej Campus)

Abstract

Gamma ray bursts (GRBs) are the intense extragalactic gamma ray flashes which last for a few milliseconds to a few hundreds of seconds. The simultaneous detection of both the gravitational wave (GW) and electromagnetic (EM) signals is the only way to probe the origin of short GRBs (flash duration<2s). Hence both sensitivity of GW and EM detectors is essential in addition to all sky coverage of EM detectors. Daksha is a proposed high energy transient mission of India providing full sky coverage with better sensitivity whose primary goal is to detect electromagnetic counterparts of gravitational wave events. In addition to the sensitivity of EM detectors, precise localisation of events is very crucial for their follow up afterglow study in other EM wave bands. The short GRB afterglow study is important since it carries signatures of elements heavier than iron formed from r-process nucleosynthesis of neutrons in the ejecta of BNS merger, also many fundamental physics can be verified from the signatures carried by these events at high redshifts. The proposed Daksha configuration estimates localization based on the ratio of photon counts on detectors at different orientations. In this work we explore the improvement of localization in Daksha if a coded mask is used for either low or medium energy detectors. For this, we have estimated both sensitivity and localization accuracy of Daksha detectors.

Large Blue Spectral Index from a Conformal Limit of a Rotating Complex Scalar

Date

2024-10-22

Speaker

Dr. Sai Chaitanya Tadepalli, Indiana University, USA

Venue

Room no: 469 (Main Campus)

Abstract

CDM isocurvature power with large blue spectral index can explain the 2-sigma hint in Planck data and recent JWST observation of high redshift galaxies. A well-known method for generating a large blue spectral index for axionic isocurvature perturbations involves a flat direction without a quartic potential term for the axion field's radial partner. In this talk, we discuss how a large blue spectral index can be achieved even with a quartic potential term linked to the Peccei-Quinn symmetry breaking radial partner. We utilize the fact that a large radial direction with a quartic term can naturally induce a “conformal limit”, producing an isocurvature spectral index of 3. Alternatively, this limit can be seen as the angular momentum of the initial conditions slowing the radial field or as a superfluid limit. The large angular momentum necessitates a careful quantization process to establish the vacuum state. We outline the parametric region that aligns with axion dark matter and isocurvature cosmology, and discuss prospects for future detection.

Graphitization for Radiocarbon Dating with AGE3: Development & challenges

Date

2024-10-22

Speaker

Mr. Ankur Dabhi

Venue

Ground Floor Lecture Hall

Abstract

Radiocarbon dating is a widely used dating technique in earth sciences and archaeology. 1MV Accelerator Mass Spectrometer at PRL has been successfully measuring radiocarbon in variety of natural samples. Graphitization is a crucial step in radiocarbon dating, enabling the transformation of carbonaceous samples into a form suitable for AMS. Graphitization with Automated Graphitisation Equipment(AGE-3) is an innovative approach designed to enhance the efficiency and accuracy of graphitization. In this talk, I will discuss the procedural advancements and optimization of graphitization with AGE3,the challenges and some results showing the quality of graphite produced with AGE-3.

Study of granite genesis through earth analogue: Bridging Earth with Moon and Mars

Date

2024-10-18

Speaker

Dr. Riya Debacharya Dutta

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The petrogenesis of granite plays a key role in understanding earth’s geological processes, and it offers insight into the history and evolution of other terrestrial planets as well. The mineral assemblage, textural association record the information about depth, temperature, composition of parental melt from which it crystallizes. Although less common, the presence of granite or granite like components in Moon and Mars can shed light on the planetary differentiation and prolonged magmatic processes. In this seminar, I will discuss the fundamentals of granite formation through petro-geochemical study of granites from Mount Abu and surrounding areas and will try to correlate the magmatic processes for genesis of granitic components in Moon and Mars.

Stellar evolution in star clusters

Date

2024-10-17

Speaker

Dr. Ranjan Kumar

Venue

Seminar Room #113 (Thaltej Campus)

Abstract

Star clusters are ideal places to explore the formation and evolution of stellar systems. They host stars of almost all the evolutionary phases. Mostly, young and massive stars dominate the open clusters, whereas the globular cluster traces the evolutionary sequence of low-mass stars. They also contain exotic stellar populations (e.g., blue straggler stars, blue hook stars, AGB-manque stars, low mass He white dwarf, and catalysis variables, etc.), which are byproducts of dense stellar environments and/or binary stellar systems in the cluster. The ultraviolet (UV) emission in star clusters is mostly dominated by the young (massive), exotic, and evolved stars, which are important to studying the formation and evolution of a star cluster. I will present the first comprehensive ultraviolet (UV) source catalogue (UVIT DR1) of UV photometry in various FUV (1300&#8722;1800 A) and NUV (2000&#8722;3000 A) filters of the UltraViolet Imaging Telescope (UVIT) onboard AstroSat. UVIT DR1 includes a total of 239,520 unique UV-bright sources, of which 70,488 sources have FUV magnitudes, and 211,410 have NUV magnitudes covering a sky area of ~ 58 sq. deg. I will showcase the results of a newly discovered hot post-AGB star in a sparse Galactic globular cluster, E3 (ESO 37-1), using UVIT observations. I will discuss its binarity, chemical abundance and evolutionary status utilizing observed/archival datasets of the UVIT/AstroSat, Gaia DR3, and high-resolution spectra. In this talk, I will also discuss the preliminary results of the study of blue straggler stars in selected star clusters using photometric and spectroscopic observations of the 2.5m telescope, Mt. Abu.

Spacewire Protocol for Planetary Instrumentation

Date

2024-10-11

Speaker

Sanjeev Kumar Mishra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Backend electronics is one of the critical subsystem of and instrumentation for planetary applications. Within the backend electronics, data handling and communication between the instrument and the spacecraft is crucial. There are many ways in which it is realized, each depending upon their unique requirents. Space agencies worldwide have different data handling and communication protocols for different missions most of which are not standardized. Spacewire is one of the first such attempt to standardize the communication protocol. In this talk, I will be providing an overview of this protocol, design and implementation plans.

Gravitational wave and multi-messenger signals from compact binary mergers

Date

2024-10-10

Speaker

Prof. Kunal Mooley

Venue

Seminar Room #113 (Thaltej Campus)

Abstract

More than 150 high-significance gravitational wave (GW) sources, primarily binary black hole mergers, have been detected by ground-based GW observatories to date. The joint GW and EM detections of the binary neutron star merger GW170817 yielded a scientific bonanza in fields as wide-ranging as gravitational physics, nucleosynthesis, neutron star equation of state, relativistic explosions and jets, and cosmology. The EM counterpart of GW170817 gave insight into the mass, speed and composition of the slow-moving merger ejecta through the rapidly-evolving kilonova emission (from r-process nucleosynthesis), while the long-lasting afterglow probed the energetics and morphology of the relativistic ejecta (jet and cocoon). It also provided an unambiguous link between neutron star mergers and short gamma-ray bursts, and facilitated a precise measurement of the Hubble's constant. I will discuss the astrophysics and fundamental physics learned from GW170817 and what could be learned from future GW events: like NS-NS and NS-BH mergers. I will also describe the searches for systems like NS-BH and high-mass-ratio systems in the Galactic Center that will be important for space-based detectors like LISA.

Molecular Characterization of Brown Carbon Using Fluorescence Spectroscopy

Date

2024-10-08

Speaker

Dr. Devprasad M.

Venue

Ground Floor Lecture Hall

Abstract

On a global scale, aerosols cool the atmosphere by scattering incoming solar radiation. However, absorbing aerosols such as black carbon (BC), brown carbon (BrC), and dust can significantly alter this effect on a regional scale. Radiative forcing (RF) estimates for BC and dust are relatively straightforward due to their simpler structures and primary emissions. In contrast, brown carbon is more complex, with a wide variety of forms and both primary and secondary sources. A detailed treatment of BrC is often lacking in climate models. Observations suggest that the RF due to BrC can be 20–40% of the RF due to BC, with even higher values reported for biomass-burning-dominated regions. A significant spatial and temporal variations have been observed in the RF of BrC, necessitating their characterization on molecular level. Various methods are used for this purpose. Among these, fluorescence spectroscopy stands out for its high sensitivity, repeatability, minimal sample preparation, non-destructive nature, and ease of operation. In this talk, I will discuss the basics of brown carbon and how fluorescence spectroscopy can be used to identify its dominant species.

Quantum aspects of the conformal sector of gravity and torsion in 4D

Date

2024-10-07

Speaker

Mr. Abbas Tinwala

Venue

Online---https://imeet.vconsol.com/viewer/5845393127?be_auth=NTIzNzU2

Abstract

"Classical conformal invariance is expected to hold quite well at energies MSM ≪ E≪ MP. so that the Standard Model (SM) particle masses, MSM, may be neglected while at the same time, quantum gravity can be assumed to contain only massless spin-2 particles. Coincidentally, consistent theory of propagating torsion coupled to SM particles is possible only for massless fermions which can be realized if E Mfer ≫ for the mass Mfer of heaviest fermions. In addition to fermions if torsion is coupled to scalar fields then the theory of propagating torsion is not possible due to unitarity violations found at the two-loop order. In this regard, recently proposed theories of composite Higgs particles which indicate that the Higgs field manifests as fermionic condensate could be a sign of relief for the torsion theory since at energies higher than the electroweak scale one ends up only with fermions (and bosons with non-zero spin). Even in this scenario, there may still be an obstacle to realizing the theory of propagating torsion since we must deal with the conformal sector of gravity. In this talk, I will show that the anomaly-induced effective action including torsion [3], consists of a scalar field representing the conformal sector of gravity coupled to torsion potentially causing similar unitary violations. A calculation of one loop and/or two loop divergences in the theory of conformal factor and torsion and a subsequent analysis of the beta functions become necessary to clarify the status of torsion as a propagating field."

Flare Response in the Photosphere and Chromosphere: A Multi-line Spectropolarimetric Study

Date

2024-10-04

Speaker

Dr. Rahul Yadav

Venue

USO Seminar Hall

Abstract

Solar flares, driven by magnetic reconnection in the corona, rapidly release immense energy into the solar atmosphere. Observations have shown that a flare influences different layers of the solar atmosphere almost simultaneously. However, it is still unclear how a flare impacts the lower solar atmosphere. Multi-line spectropolarimetric observations, covering different layers, are necessary to present a comprehensive view of flares. In this talk, I will explore the lower atmospheric response to flares using multi-line spectropolarimetric observations. I will demonstrate how these observations, combined with state-of-the-art multi-line inversion code, can be used to construct a stratification of physical parameters such as temperature, magnetic field vector, line-of-sight velocity, and macroturbulent velocity within a flaring atmosphere. The resulting semi-empirical model will be directly compared with theoretical flare models. Additionally, I will present recent findings from the 4-meter Daniel K. Inouye Solar Telescope, focusing on the rotation of pores associated with flares on a significantly smaller scale.

Understanding the Space Weather Impact of Coronal Mass Ejections Utilising Observations and Modelling

Date

2024-09-30

Speaker

Dr. Ranadeep Sarkar

Venue

USO Seminar Hall

Abstract

The most challenging problem in space weather research is to predict the intensity of geomagnetic storms at Earth. During these storms modern infrastructure in space and on ground can experience significant hazards, such as disruptions of communication and power lines, and malfunctions or even a failure of satellites in orbit. The storms occur when an Earth-directed interplanetary coronal mass ejection (ICME) and/or their frontal sheath carries a strong southward interplanetary magnetic field (IMF) Bz. Therefore, the prediction of Bz inside both the ICME and sheath regions, is the prime requirement to forecast the severity of geomagnetic storms. Since the magnetic field of solar eruptions cannot reliably be measured via remote means, and direct continuous measurements of the Earth impacting solar transients are routinely available only very close to our planet, modelling of CME magnetic properties is paramount. In this talk, I will present a space weather modelling framework using both analytical and global MHD approaches that could prove to be an operation space weather forecasting tool to predict the geo-effectiveness of CMEs. This talk will also showcase the utilisation of multi-wavelength remote-sensing observations as well as multi-spacecraft in-situ observations at different heliocentric distances to constrain the space weather forecasting models. I will further discuss how data from India's space-based solar observatory, Aditya L1, and ISRO’s upcoming mission to Venus will play a crucial role in enhancing our understanding on the initiation and space-weather effects of CMEs.

Understanding the Space Weather Impact of Coronal Mass Ejections Utilising Observations and Modelling

Date

2024-09-30

Speaker

Dr. Ranadeep Sarkar, Postdoctoral Fellow, Space Physics Department, University of Helsinki

Venue

USO Seminar Hall

Abstract

The most challenging problem in space weather research is to predict the intensity of geomagnetic storms at Earth. During these storms modern infrastructure in space and on ground can experience significant hazards, such as disruptions of communication and power lines, and malfunctions or even a failure of satellites in orbit. The storms occur when an Earth-directed interplanetary coronal mass ejection (ICME) and/or their frontal sheath carries a strong southward interplanetary magnetic field (IMF) Bz. Therefore, the prediction of Bz inside both the ICME and sheath regions, is the prime requirement to forecast the severity of geomagnetic storms. Since the magnetic field of solar eruptions cannot reliably be measured via remote means, and direct continuous measurements of the Earth impacting solar transients are routinely available only very close to our planet, modelling of CME magnetic properties is paramount. In this talk, I will present a space weather modelling framework using both analytical and global MHD approaches that could prove to be an operation space weather forecasting tool to predict the geo-effectiveness of CMEs. This talk will also showcase the utilisation of multi-wavelength remote-sensing observations as well as multi-spacecraft in-situ observations at different heliocentric distances to constrain the space weather forecasting models. I will further discuss how data from India's space-based solar observatory, Aditya L1, and ISRO’s upcoming mission to enus will play a crucial role in enhancing our understanding on the initiation and space-weather effects of CMEs.

Exploring the Spectral and Physical characteristics of Lunar Pyroclastic Deposits

Date

2024-09-27

Speaker

Dibyendu Misra

Venue

Online

Abstract

Lunar Pyroclastic Deposits (LPDs) play a key role in understanding the explosive volcanic activity on the Moon. These deposits consist of partially crystallized volcanic glasses, which retain essential information about the primary lunar mantle composition. However, the remote identification of these volcanic glasses is challenging, due to their similar spectral characteristics to common lunar minerals in the visible to near-infrared wavelength range. In this seminar, I will introduce a novel approach for detecting and characterizing LPDs, utilizing the Chandrayaan-1 Moon Mineralogy Mapper data. Additionally, I will discuss insights into the surface behavior of these deposits through multispectral imaging polarimetric data obtained from Mount Abu. The results derived using the newly proposed method will be discussed by considering a few typical case studies of known pyroclastic deposits.

Resonant and Secular Evolution of Three Body Systems – With Applications to Planetary Systems and Gravitational Wave Sources

Date

2024-09-26

Speaker

Dr. Hareesh Gautham Bhaskar

Venue

Seminar Room #113 (Thaltej Campus)

Abstract

The three-body problem describes the motion of three objects under the influence of their mutual gravity. It is one of the oldest problems in astrophysics. No closed form analytical solution is possible to the general three body problem due to its chaotic nature. Despite its rich history, the three-body problem remains an active area of research. Recent advancements in the field are motivated by new discoveries pertaining to exoplanets and blackholes. In this work we focus on resonant and secular interactions in three body systems, with a goal to understand how these interactions influence the long-term stability and evolution of three body systems. We apply our theoretical investigations of these physical processes to a wide range of observed systems. We find that secular and resonant perturbations can significantly affect the stability limit of mutually inclined planets. Planets in retrograde configurations are much more stable than prograde configurations, with secular perturbations significantly destabilizing the system when 200 < Imut < 1600. In addition, we find that secular three body dynamics can also help us constraint the inclination of the hypothetical Planet-9 in the outer solar system, and explain the observed retrograde stellar obliquities of hot Jupiters. We also propose a novel pathway through which compact binaries could merge due to eccentricity excitation caused by resonant interactions induced by a massive coplanar companion. Specifically, a compact binary migrating in an AGN disk could be captured in a precession-induced resonance, when the apsidial and nodal precession rates of the binary are commensurable to the orbital period around the supermassive black hole. Eccentricity is excited when the binary sweeps through the resonance which happens only when it migrates on a timescale 10-100 times the libration timescale of the resonance. The eccentricity excitation of the binary can reduce the merger timescale by a factor up to 103 -105.

Josephson diode effect in a quantum dot junction

Date

2024-09-24

Speaker

Dr. Debika Debnath

Venue

Room no: 469 (Main Campus)

Abstract

I will discuss the Josephson diode effect (JDE) in a quantum dot (QD)-based Josephson junction (JJ) in the presence of an external magnetic field and Rashba spin-orbit interaction (RSOI). To achieve the diode effect in the JJ, we break the time-reversal symmetry through the Zeeman field, and the inversion symmetry is broken by RSOI. We calculate the Josephson current using the Keldysh nonequilibrium Green’s function technique. Our QD with RSOI induces JDE in the heterojunction with a large rectification coefficient (RC) that can be tuned to be as high as 70% by an external gate potential, indicating a giant JDE in our QD junction. Interestingly, we find that the sign and magnitude of the RC are highly controllable by the magnetic field and RSOI. We also investigate the role of electron-electron correlation to the Josephson diode by incorporating an interacting QD as the intermediate tunnelling medium. Our proposed QD–based Josephson diode (JD) has the potential to be an efficient superconducting device component.

Riverine carbon and nitrogen biogeochemistry in critical zone sites in the western India

Date

2024-09-24

Speaker

Mrs. Sangeeta Verma

Venue

Ground Floor Lecture Hall

Abstract

पश्चिमी भारत में महत्वपूर्ण क्षेत्र स्थलों में नदी कार्बन और नाइट्रोजन जैव-भू-रसायन

Temperature Profiles and Radiative Transfer Modeling of Protoplanetary Disks

Date

2024-09-20

Speaker

Soumik Kar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

A protoplanetary disk is a rotating circumstellar disk composed of dense gas and dust around a recently formed young star. Understanding its evolution is essential to understanding the planet's formation. Volatiles, encompassing diverse compounds such as water, carbon dioxide, and complex organic molecules, significantly impact the composition and characteristics of growing planetary bodies. First, we will discuss the disks' basic properties from observations and numerical models. It will help us understand the complex dynamics that shape the overall structure of protoplanetary disks and influence the spatial distribution of volatiles. Then, we will discuss these disks' radial and vertical temperature profiles, probing the thermal conditions that drive volatile transport and chemical reactions. Finally, we will discuss the radiative transfer code, which calculates the disk temperature using the Monte Carlo technique and discuss the first results.

Contact Binaries: A Detailed Analysis Through Photometric and Spectroscopic Data

Date

2024-09-19

Speaker

Dr Alaxender Panchal

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Eclipsing binaries (EBs) are essential for understanding stellar evolution, providing direct measurements of stellar masses, radii, and luminosities. Among these, W UMa-type systems, also known as contact binaries, are particularly important because the stars share a common envelope, leading to complex energy exchanges. W Uma-type systems are important as they give information about component interactions, mass-trasfer between components, period evolution, extra bodies around inner binary etc. In this talk, I will present a long-term photometric and spectroscopic analysis of four W UMa-type systems. This study combines light curves with spectroscopic data, revealing details about their orbital parameters, period changes, and evolution. The findings shed light on the internal dynamics of contact binaries, offering valuable insights into stellar interaction and evolution. I will discuss the methods used, the findings, and their significance in the broader context of contact binaries.

Quasiperiodic potential induced corner states in a quadrupolar insulator: A paradigm for higher-order topology

Date

2024-09-18

Speaker

Prof. Saurabh Basu

Venue

Room no: 469 (Main Campus)

Abstract

The topological and localization properties of a quadrupolar insulator represented by the celebrated Benalcazar-Bernevig-Hughes model is studied in presence of a quasiperiodic disorder. While disorder is expected to disturb the existence of topological order in a system, we observe that a disorder driven topological phase emerges where the original (clean) system demonstrates trivial behavior. This phenomena is confirmed by the re-emergence of the zero energy states together with the non-trivial values of the quadrupole moment. Moreover, the distribution of the excess electronic charge shows a pattern that clearly corresponds to the bulk quadrupole topology. To elaborate upon the localization properties of the mid-band states, we compute the inverse participation and normalized participation ratios. It is observed that the in-gap states become critical (multifractal) at the point that discerns a transition from a topological localized to a trivial localized phase. Finally, we carry out a similar investigation to ascertain the effect of the quasiperiodic disorder on the quadrupolar insulator when the model exhibits topological properties in the absence of disorder. Again, we note a multifractal behavior of the eigenstates in the vicinity of the transition.

Introduction to Artificial Intelligence

Date

2024-09-13

Speaker

Dr Y B Acharya

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Artificial Intelligence has grown to be very popular in today’s world. It is the simulation of natural intelligence in machines that are programmed to learn and mimic the actions of humans. These machines are able to learn with experience and perform human-like tasks. As technologies such as AI continue to grow, they will have a great impact on our quality of life. It’s but natural that everyone today wants to connect with AI technology somehow, may it be as an end-user or pursuing a career in Artificial Intelligence.

Unraveling the mysteries of Harappan Ernestite: A Geochemical prospective

Date

2024-09-10

Speaker

Dr. Milan Mahala

Venue

Ground Floor Lecture Hall

Abstract

The Harappan (Indus Valley) civilization, one of the most sophisticated Bronze Age civilizations, survived for over two millennia (5300-2600 yrs BP) in the alluvial plains of the northwestern Indian subcontinent. The Harappan Gujarat was the center of bead manufacturing activities and inter-regional trade networks. The Harappans, known as master crafters and traders of their period, manufactured beads of agate, carnelian, jasper, terracotta, etc., for ornaments and trading purposes. Besides thousands of beads discovered, numerous stone drill bits have also been found from many Harappan sites. These drill bits are believed to have been ground out from certain hard stones, which have been named Ernestites. The origin of Ernestite remains an enigma because it does not resemble any natural rock. If produced artificially, what raw materials were used, and what process was followed in their making? Since deciphering the origin of Ernestite is essential for understanding the manufacturing abilities of these Bronze Age people, we undertook a detailed petrographic, geochemical, and isotopic study of the Ernestites from multiple sites in Gujarat. In this seminar, I shall discuss our findings.

Pseudogap in

Date

2024-09-05

Speaker

Dr. Jalaja Pandya

Venue

Room no: 469 (Main Campus)

Abstract

Gor'kov and Teitel'baum formulated a phenomenological model for the number of charge carriers, derived from the Hall effect data of La2-xSrxCuO4. The activation energy obtained from this model agreed well with the pseudogap signatures observed in the angle resolved photoemission spectroscopy. Recently, Hall effect measurements are done on Lanthanum doped Strontium Iridate

Efficient Quantum Field Theories for Quantum Computers

Date

2024-09-03

Speaker

Dr. Debashis Banerjee

Venue

Room no: 469 (Main Campus)

Abstract

"Computing methods on classical computers have dominated the discovery frontline from fundamental physics for several decades now. It is however becoming clear that at least in physics, there are several computational avenues (such as finite density and real-time dynamics) where development can be accelerated via quantum computers. At the same time, improving classical computing techniques using clever analytical insights is essential to provide further inputs to the quantum computing frontier. In this talk, we will discuss the broad ideas behind the novel constructions and selected applications illustrating results for realistic systems in condensed matter and particle physics. Such scenarios are expected to be realized in quantum hardware in the recent future."

Advances in integrating petrochronological and geodynamic models of high-grade metamorphic systems

Date

2024-09-03

Speaker

Prof. Chris Clark

Venue

Ground Floor Lecture Hall

Abstract

The field of metamorphic petrology has undergone several evolutions beginning with the recognition that certain groupings of minerals reflect thermobaric conditions (index minerals and the facies concept of Eskola). This was followed by the realisation that these same minerals partition elements in a systematic way allowing temperatures and pressures to be quantified (classical thermobarometry) and that whole systems can be mapped in thermodynamic space to generate phase diagrams that capture the evolution of a rock (the pseudosection approach of Holland and Powell in the late 80’s early 90’s). These evolutions have progressed in lock step with the evolution of analytical capabilities that facilitate the collection of chemical (electron microprobes) and isotopic (SIMS and laser ablation mass spectrometry) information from mineral grains that enable the pressure-temperature-time (P–T–t) histories of rocks to be constrained (the field of “Petrochronology” pioneered by researchers such as Daniela Rubatto and Brad Hacker in the early 2000’s). Despite these advances we are still faced by the challenge that the rocks we collect and analyse provide only a snapshot of the journey a single sample takes through an orogenic (mountain building) cycle. A potential path to address this issue is the application of diffusion geospeedometry where the zoning profiles of different mineral can be used to construct a detailed temperature–time history for rocks – as always, a key mineral in this endeavour is garnet. Diffusion chronometry coupled with thermochronometers and 4+ cation thermometers allow more detail on P–T-t paths to be constrained. However, there now exists a dichotomy in the results produced by each approach wherein diffusion based geospeedometry studies generally yield timescales that are orders of magnitude faster that the classical U–Pb geochronological investigations. Begging the question how much of an orogenic evolution are we capturing and are orogenic events long and slow or constructed through a series of pulses? In this talk I will present progress towards the integration of phase diagram tools, diffusion processes, geochronological and petrological datasets with geodynamic models to constrain the evolution of lower crustal rocks during orogenic cycles. This approach, in our opinion, is the obvious next evolution in metamorphic petrology and is being enabled by the concomitant advances in both open-source geodynamic codes, in this case Underworld, and increasing computational power (both at the desktop and supercomputer level). These developments enable individual researchers to develop and test multiple scenarios to see what is plausible based on real geological data and the physics of rock systems at their desk rather than waiting for access to scarce resources such as access to national supercomputer facilities

Noble gases & Nitrogen isotopes: Results from Noble gas mass spectrometer lab

Date

2024-08-30

Speaker

Ramakant R. Mahajan

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Results from noble gas mass spectrometry lab. will be discussed. Isotopes of noble gases and nitrogen in meteorites provide important information about the formation and evolution of the solar system and beyond.

(1) Chandrayaan-3 APXS elemental abundance measurements: Confirmation of Lunar Magma Ocean hypothesis and ground truth for future remote sensing observations in the southern polar highland region (2) Multiple sources of water in impact glasses from Change-5 lunar soil

Date

2024-08-23

Speaker

Prof Debabrata Banerjee

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The presentation will discuss OH and molecular H2O related to solar wind and other multiple sources preserved in impact glasses from Chang’e-5 (CE5) lunar soil based on observations of reflectance infrared spectroscopy and nanoscale secondary ion mass spectrometry analyses.

"Non-equilibrium (hot) electron relaxation: Review of the ultrafast phenomena in metals and superconductors. "

Date

2024-08-22

Speaker

Prof. Navinder Singh

Venue

Room no: 469 (Main Campus)

Abstract

"This field effectively originated when Kaganov, Lifshitz and Tantarov in 1957 put forward their famous Two-Temperature Model (TTM) of non-equilibrium electron relaxation in metals. During the ensuing decades much advance happened due to the advent of femtosecond lasers. In this talk, a chronological review of the field will be presented in which relaxation of hot (non-equilibrium) electrons in semiconductors and superconductors will be discussed. Some works done in PRL in this field will be reviewed. Recent advancement of photo-induced superconductivity will also be discussed."

NLP corrections for H+ jet production

Date

2024-08-21

Speaker

Dr. Sourav Pal, PDF

Venue

Room no: 469 (Main Campus)

Abstract

Precise experimental data from the Large Hadron Collider and the lack of any persuasive new physics signature demand improvement in the understanding of the Standard Model.The scattering cross-sections are plagued with Leading power (LP) and next-to-leading power (NLP) logarithms. Resummation of LP logarithms has a long history of almost three decades and their resummation methods are well known in the present literature. However, precise prediction also requires the resummation of NLP logarithms, as they have a sizeable numerical impact in the cross-section calculation. These NLP logarithms for colour singlet processes are well known in the literature, however, there is a scarcity of results when final state colour particles are involved in the scattering process. In the talk, I will discuss a new method of calculating the NLP logarithms where final state colour particles are involved and will show its application for Higgs+ jet production.

THE MARINE BIOGEOCHEMICAL CYCLE OF SILICON: INSIGHTS FROM SILICON STABLE ISOTOPES

Date

2024-08-20

Speaker

Mr. Mahesh Gaddam

Venue

Ground Floor Lecture hall

Abstract

Silicon (Si) is the second most abundant element in the Earth’s crust and is an important nutrient in the ocean. The global Si cycle plays a critical role in regulating primary productivity and carbon cycling on the continents and in the oceans. Silicon has a complex biogeochemical cycle, interacting with other globally important elemental cycles (e.g Carbon and Nitrogen). Dissolved silicon (DSi) and its isotopes (&#948;30SiDSi) are powerful tool for understanding biogeochemical and ocean processes. In this talk, an outline of Si cycle, along with the measurement methods and application of Si isotope composition in seawater will be discussed.

Study of Martian atmosphere over Hellas and Argyre regions

Date

2024-08-16

Speaker

Ms. Gayatri Sharma

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

It is known that the Mars consist major gas CO2. The average surface temperature of Mars is about 220 K. The mean surface pressure of Mars is about 6 mbar. Recently, Emirates Mars Infrared Spectrometer(EMIRS) onboard Emirates Mars Mission(EMM) measured surface temperatures at all latitudes and longitudes during spring, summer, autumn and winter seasons. We have analyzed these data and preliminary results over Hellas (42.4°S, 70.5°E) and Argyre (49.75°S, 316°E) regions will be presented in this seminar. In these craters the average surface temperature ~300 K and~160 K are observed during summer and winter respectively. Thus, the temperature values plummet by ~140 K during winter of these basins. It is also found that southern hemisphere's summer is warmest than the northern hemisphere's summer, because Mars is closest to the sun in Southernhemisphere's summer.

Implications of decaying neutrino state in the Bi-magic baseline

Date

2024-08-16

Speaker

Dr. Supriya Pan, PDF

Venue

Room no: 469 (Main Campus)

Abstract

"The neutrino oscillations have established that there are massive neutrino mass states. The well-understood framework of standard three-flavor neutrino oscillation gives us the scope to look for signatures of new physics beyond the Standard Model. One such scenario is when heavier neutrino states decay into lighter ones, first proposed to describe the zenith-angle dependence in atmospheric-neutrino data at Super-Kamiokande. The baseline of 2540 km has a special feature where the sensitivity to mass hierarchy is very high at probability maxima. In our work, we study how the presence of decay of the heaviest neutrino state will impact the sensitivity to mass-hierarchy and the octant of angle theta23 using the proposed setup of Portvino to ORCA (P2O) experiment at a baseline of 2588 km."

Paleo-pCO2 Reconstructions in the Equatorial Indian Ocean using Boron Isotopic Records of Planktonic Foraminifers

Date

2024-08-13

Speaker

Dr. Sanjit Kumar Jena

Venue

Ground Floor Lecture hall

Abstract

Carbon dioxide (CO2) constitutes around 80% of the global greenhouse gases in the present atmosphere significantly contributing to global warming and its major climatic consequences such as the melting of ice sheets, sea level rise, ocean acidification and extreme weather events. The global ocean with its substantial storage and exchangeability plays a crucial role in regulating the widespread distribution of atmospheric pCO2, thereby influencing regional and global climatic changes. Reconstruction of past oceanic CO2 is essential to understand the temporal evolution of the climate, helping predict its future trends. Boron isotopic records in planktonic foraminifers offer a key method to reconstruct past oceanic CO2 records. However, precise measurement of boron isotopes has remained a major challenge, especially from mass limited foraminifera samples subject to contamination and isotopic mass fractionation issues. This talk will highlight the potential implications of paleo-pCO2 reconstructions in the Equatorial Indian Ocean to the global paleoclimatic research, and glimpses of the methodological advancements in extraction and precise measurement of boron isotopes in planktonic foraminifera samples.

1D Photochemical Model for Venusian Ionosphere

Date

2024-08-09

Speaker

Satyandra M Sharma

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The dayside Venusian ionosphere is primarily formed due to photoionization and photoelectron impact ionization of the neutral atmosphere by Solar EUV (15-100 nm) and soft X-rays (1-15 nm) radiations. These processes result in the formation of the V2 (~140km) and V1(~125km) layers in the ionosphere. Additionally, a sporadic layer, V0(~113km), observed below the V1 layer, is suspected to be of photochemical origin, though its exact source remains unidentified. We have developed a photochemical model of the dayside Venusian ionosphere, which has been validated against the electron density profile observations from the Venus Radio Science (VeRa) experiment onboard the Venus Express (VEX). In this seminar, I will discuss about the modeling of the Venus ionosphere.

Insights into High-Resolution Time-of-Flight Aerosol Mass Spectrometry (HR-ToF-AMS): Principles, Components, and Applications

Date

2024-08-06

Speaker

Mr. Rohit Meena

Venue

Ground Floor Lecture hall

Abstract

High-Resolution Time-of-Flight Aerosol Mass Spectrometry (HR-ToF-AMS) represents a significant advancement in atmospheric chemistry and aerosol science. This technology combines high-resolution mass spectrometry with time-of-flight to measure real-time, non-refractory, size-resolved particulate chemical composition and mass. It facilitates a deeper understanding of aerosol dynamics, source apportionment, and their impacts on air quality and climate. In this talk, I will cover the fundamentals of HR-ToF-AMS, its key components, and their functions and its application.

Chandrayaan-3 and Changing Perspectives of the Moon

Date

2024-08-02

Speaker

Dr. K. Durga Prasad

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The glorious landing of Chandrayaan-3 at a high latitude location on the Moon was definitely a mesmerising moment for all Indians, particularly for those working for the mission for more than a decade. In addition to providing the first-ever measurements of a never-explored territory, the mission has provided an entirely new perspective of the Moon with its in-situ measurements. ChaSTE is an experiment onboard Chandrayaan-3 lander aimed at investigating the thermophysics at the landing site. After successful landing of Vikram at Shiv Shakti point, ChaSTE probe was deployed and successfully penetrated into the lunar soil to provide the first-ever in-situ thermal measurements at a lunar high latitude location. An insight into lunar thermophysics, experimental challenges, surprises and mission experiences will be discussed.

Assembly-Integration-Testing of ProtoPol, its on-sky commissioning, and subsequent status of its data reduction pipeline

Date

2024-08-01

Speaker

Arijit Maiti

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

ProtoPol is a medium-resolution echelle spectro-polarimeter initially conceived as the prototype instrument of the currently under development M-FOSC-EP (Mt. Abu Faint Object Spectrograph and Camera-Echelle Polarimeter) instrument – a two-channel multimode instrument which is currently being designed for PRL 2.5m telescope at Mt. Abu. Though ProtoPol was initially conceived to evaluate the development methodology of M-FOSC-EP using commercially available off-the-shelf components, it was later elevated to the level of a full-fledged back-end instrument for PRL telescopes. ProtoPol was designed on the concept of echelle and cross-disperser gratings to record the cross-dispersed spectra in the wavelength range from 390 to 940 nm with a resolution in the range of 7000-8000. ProtoPol has been successfully developed and commissioned on PRL 1.2m and 2.5m telescopes since December 2023, and a variety of observations are being carried out for instrument characterization and scientific purposes. In this talk, I shall discuss the features and properties of ProtoPol, the assembly-integration-testing of the instrument in the laboratory, and its subsequent commissioning on PRL telescopes for on-sky characterization and science observations. I will also talk about the current status of the data reduction pipeline being developed for ProtoPol.

Beyond standard hydrodynamics: “maximum-entropy” theory and the dynamics of critical fluctuations

Date

2024-08-01

Speaker

Dr. Chandrodoy Chattopadhyay

Venue

Room no: 469 (Main Campus)

Abstract

I will present formulation of ‘maximum-entropy hydrodynamics’, a far-off-equilibrium macroscopic theory that effectively describes both free-streaming and near-equilibrium regimes of the quark-gluon plasma formed in heavy-ion collisions. Unlike standard hydrodynamic theories this formulation incorporates contributions to all orders in shear and bulk inverse Reynolds numbers, allowing it to handle large dissipative fluxes. By considering flow profiles relevant for nuclear collisions at high energies, I will demonstrate that ‘maximum-entropy hydrodynamics’ provides excellent agreement with underlying kinetic theory throughout the fluid’s evolution, especially in out-of-equilibrium regimes where traditional hydrodynamics becomes inapplicable. I will then present formulation of stochastic fluid dynamics to model the evolution of critical fluctuations in a system that is close to a critical point. I will demonstrate that correlation functions of the order parameter exhibit dynamical scaling behavior which is sensitive to the correlation length and shear viscosity of the fluid. I will also show that non-linear interactions between shear modes constrain the minimum value of a fluid’s shear viscosity.

Heavy-ion collisions and hydrodynamics

Date

2024-07-31

Speaker

Dr. Chandrodoy Chattopadhyay

Venue

Room no: 469 (Main Campus)

Abstract

Relativistic heavy-ion collisions at LHC, CERN and RHIC, BNL produce a novel state of matter, the quark-gluon plasma (QGP), where the fundamental constituents of nucleons, i.e., quarks and gluons, become deconfined over nuclear volumes. Understanding the thermodynamic and transport properties of QGP constitute one of the major goals of high energy nuclear physics. In this talk, I shall give an overview of heavy-ion collisions and describe how hydrodynamics plays a fundamental role in the modeling of such collisions. I will present how relativistic dissipative hydrodynamics can be systematically formulated using kinetic theory and outline the development of a macroscopic theory that is applicable even in far-off-equilibrium regimes where traditional hydrodynamics breaks down. I will also discuss the incorporation of thermal fluctuations in hydrodynamics and their role in extracting the transport properties of QGP using final state observables of heavy-ion collisions.

Ocean Alkalinity Enhancement: A redemption?

Date

2024-07-30

Speaker

Ms. Shreya Mehta

Venue

Ground Floor Lecture Hall

Abstract

The increased global emissions of greenhouse gases due to anthropogenic activities have led to an increase in climate warming, with present-day mean atmospheric temperature reaching 1.1°C above the preindustrial level. The alarming increase in greenhouse gas emissions has motivated the discussion of climate change and the need to limit the emissions so as to limit the warming below 1.5°C or 2.0°C by the year 2100. To combat this and limit the warming below 1.5°C or 2.0°C by the year 2100, along with reducing CO2 emissions, Negative Emission Techniques (NETs) or Carbon Dioxide Removal (CDR) methods are required. Ocean Alkalinity Enhancement (OAE) is one of the NETs, but uncertainties surround the feasibility and consequences of implementing OAE on a global scale. To address this, we conducted mesocosm experiments in the coastal waters of the Arabian Sea. In this talk, I shall be discussing some of the preliminary findings from these experiments.

FiberPol-6D- Spectropolarimetric Integral Field mode for the SAAO 1.9 m Telescope using fibers

Date

2024-07-29

Speaker

Dr Siddharth Maharana

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Most optical spectropolarimeters built to date operate as long-slit or point-source instruments; they are inefficient for observations of extended objects such as galaxies and nebulae. 2D spectropolarimetry technique development is a major challenge in astronomical instrumentation. At the South African Astronomical Observatory (SAAO) FiberLab, we are developing a spectropolarimetry capable Integral Field front-end called FiberPol(-6D) for the existing SpUpNIC spectrograph on the SAAO 1.9 m telescope. SpUpNIC is a general purpose 2 arc-minute long-slit spectrograph with a grating suite covering the wavelength range from 350 to 1000 nm. FiberPol generates 6D observational data: x-y spatial dimensions, wavelength, and the three linear Stokes parameters I, q and u. Using a rotating half-wave plate and a Wollaston prism, FiberPol executes two-channel polarimetry, and each channel is fed to an array of 14 fibers, corresponding to a field of view of 10×20 arcseconds^2 sampled with 2.9 arcsecond diameter fiber cores. FiberPol aims to achieve a polarimetric accuracy of 0.1 % per spectral resolution bin. Further, it can also function as a non-polarimetric integral-field unit. The primary science goals include study of ISM of nearby galaxies to test the models of dust grain alignment and its dependence with the ambient magnetic field. The instrument design has been completed and it is currently being assembled and characterized in the lab. It is scheduled for on-sky commissioning in the second half of 2024. In this talk, I will present the scientific and technical goals of FiberPol, its overall design and initial results from the lab assembly and testing. FiberPol is a low cost technology demonstrator for 10m SALT and other large telescopes such as the 30m class telescopes. It can be modified and replicated for use on any existing spectrograph, especially on bigger telescopes.

Chandrayaan-3 Mission: Exploring the Moon

Date

2024-07-26

Speaker

Dr. S. Vijayan

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Chandrayaan-3 mission successfully landed on the south pole/high latitude region of the Moon overcoming all the challenges during the landing. One of the major challenges in landing from this high latitude region is the high density of impact craters with various diameter ranges. This high density of impact craters was used to understand and explore this region in detail. Also this high latitude region is not explored by any insitu lander/rover and thus Chandrayaan-3 provided the first insitu insights about the lunar highland terrain near the south pole region. In this talk, I will be providing some new insights from the Chandrayaan-3 landing site region, which will unravel the unexplored part of this landing site. I will also highlight the source materials located within and around the Chandrayaan-3 site, which are crucial to interpret the insitu derived measurements. Chandrayaan-3 landing site region have been extensively reworked/modified by the impacts and the redistribution of material affected the lunar crust over this region extensively. In this talk, I will also discuss other landing site insitu images and bring out how the Chandrayaan-3 landing site region is similar/different from the other parts of the Moon.

Graphitisation for Radiocarbon Dating : Advancement with AGE-3 & challenges

Date

2024-07-23

Speaker

Mr. Ankur Dabhi

Venue

Ground Floor Lecture Hall

Abstract

Radiocarbon dating is a widely used dating technique in earth sciences and archaeology. 1MV Accelerator Mass Spectrometer at PRL has been successfully measuring radiocarbon in variety of natural samples. Graphitisation is a crucial step in radiocarbon dating, enabling the transformation of carbonaceous samples into a form suitable for AMS. Graphitisation with Automated Graphitisation Equipment(AGE-3) is an innovative approach designed to enhance the efficiency and accuracy of graphitisation. In this talk, I will discuss the procedural advancements and optimization of AGE3, pre-treatments for different organic and inorganic samples which streamlines carbon extraction and reduces contamination ,the challenges with AGE3 and some results showing the quality & reliablity of graphite produced with AGE-3.

Signature of the vertical mixing in the atmosphere of hydrogen hydrogen-dominated exoplanet atmospheres

Date

2024-07-19

Speaker

Dr. Vikas Soni

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The disequilibrium processes in an exoplanet's atmosphere can alter the atmospheric composition from its thermochemical equilibrium abundance. The strength of these processes depends upon the several physical parameters. The characterization of the atmosphere of exoplanets has entered a phase where the observed spectral signature can probe the disequilibrium chemistry in the atmosphere of this exoplanet. Atmospheric retrieval is commonly used to constrain atmospheric abundance and parameters. Retrieval models employ the observed spectrum to constrain parameters by navigating an N-dimensional parametric space through numerous forward models. However, the effect of disequilibrium processes in the observed spectrum of exoplanets depends upon the planet to planet. In this talk, I will discuss the atmospheric retrieval model and how one can use these models to find atmospheric parameters from the observed spectrum. I will also share my recent finding on constraining the strength of vertical mixing through atmospheric retrieval. In this study, we have explored the signature of disequilibrium chemistry in the parameter space of Kzz, surface gravity, internal temperature, metallicity and equilibrium temperature. We explore the retrieval model's effectiveness, including the vertical mixing as a quenching approximation. We run several 1D chemical kinetics models in large parameters and explore the excess in the transmission signature due to the vertical mixing. We run the retrieval model for the JWST simulated spectrum and explore how effectively the excess signature of the vertical mixing can constrain Kzz.

Multi-wavelength study of Blazars

Date

2024-07-18

Speaker

Dr. Avik Kumar Das

Venue

Online : https://imeet.vconsol.com/join/5555049068?be_auth=NzQwNjQ0

Abstract

Blazars are a special subclass of active galactic nuclei, with relativistic jets pointing close to observers’ line of sight, making them the most luminous and rapidly variable extra-galactic sources in the universe. Their observed emissions are highly Doppler boosted and observable across the entire accessible electromagnetic spectrum (from radio to gamma-rays), with diverse variability timescales ranging from minutes to years. The observed emissions imply extreme physical conditions that are beyond replication by any current or future terrestrial laboratory. Almost every aspect, from jet formation, collimation to gamma-ray production in the jets, is poorly understood. However, over the past decade, the availability of long-term, high-cadence data in the multi-wavelength regime (i.e., optical, X-ray, and gamma-ray) has been helpful in addressing some aspects of these issues through study of i) multi-wavelength flux and spectral variability on diverse time scales, ii) physical origin of quasi periodic oscillations (QPOs) observed in the light curves, iii) multi-wavelength flux distribution of Blazars. In this talk, we will discuss our recent interesting results on the above topics related to Blazar emission properties.

Late Quaternary Turbidite deposits in the eastern Bay of Bengal

Date

2024-07-16

Speaker

Dr. Prajith

Venue

online

Abstract

The Bay of Bengal is an enormous repository of continent-derived sediments stored in the world’s largest submarine fan, the ‘Bengal Fan’. Huge loads of sediments from the Himalayas, Indo-Burman ranges, and Peninsular India were transferred to the deep sea through the submarine channels developed on the Bay of Bengal seafloor. Currently, only one channel is active in supplying sediment to the Bengal Fan, whereas other channels are disconnected (inactive) from the land. Much about the evolution of the fan and its controlling factors, particularly the timings of major fluctuations in turbidite activity, is unknown. This work is based on sedimentological, geochemical, and Sr-Nd isotopic records from a gravity core collected from the now-defunct submarine channel E7 in the Bengal Fan to examine the roles of various environmental factors on the growth of the fan. Our results suggest that turbidite deposition through channel E7 was active during 27 to 12 kyrs and hemipelagic sedimentation started from 12 kyr BP to present. This work highlights the complex interplay between the climate and coastal geomorphology in the growth of the fan.

Effects of disorder on flat bands of some tight binding models.

Date

2024-07-12

Speaker

Bharathiganesh D.

Venue

Room no: 469 (Main Campus)

Abstract

The effects of disorder on condensed matter systems where electrons move from one site to another by means of quantum mechanical diffusion described by tight binding models has garnered a lot of interest recently. In one dimension disorders almost always leads to localisation of electrons for lattices of reasonably big size. On the other hand, geometry of the lattice may lead to localisation of electrons at particular sites due to the onset of flat bands. In this talk we will discuss a system where both these localisation effects are present i.e. effects of different disorders on a system with flat bands and the net result of these effects.

Chandrayaan-3 mission and way ahead: Observations, challenges and evaluations

Date

2024-07-12

Speaker

Dr. Rishitosh Kumar Sinha

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The successful soft-landing of India’s third lunar exploration mission, Chandrayaan-3, was a life-changing moment. It taught numerous lessons, expedited the execution of state-of-the-art technologies, solidified current understanding, introduced new challenges, and eventually opened up a multitude of fresh opportunities for the entire generation of scientists working in the space domain. This mission has involved a significant amount of work in its realization, execution, and post-implementation stages. In this seminar, I will concentrate on the Chandrayaan-3 related work that has been done recently using data analysis from remote sensing. I will highlight the challenges faced and present my evaluations of recently published studies. Finally, I'll wrap up by highlighting important facets of lunar geology that, in my opinion, represent the most significant scientific gaps in our knowledge of the Moon's evolutionary past.

Minimal Z' for Radiative mechanism

Date

2024-07-09

Speaker

Gurucharan Mohanta, SRF

Venue

Room no: 469 (Main Campus)

Abstract

We discuss a mechanism in which the masses of the third, second, and first generation charged fermions are generated at tree level, 1-loop, and 2-loop levels, respectively. In this mechanism, loop-induced masses are obtained through fermionic self-energy corrections induced by heavy gauge bosons of a new single flavorful $U(1)_F$ symmetry, which have flavor-violating interactions with Standard Model fermions. Phenomenologically, the flavor-violating couplings $Q_{ij}$ are desired to have $|Q_{12}|<|Q_{23}|,|Q_{13}|$ because constraints from $K^0$-$\overline{K}^0$ mixing and $\mu$-$e$ conversion in nuclei, involving first and second family fermions, are more stringent than others. We establish a framework to achieve this condition and quantify the optimal flavor violations required to implement the radiative mass generation mechanism.

Isotopic record of Earth's accretion and early evolution

Date

2024-07-09

Speaker

Dr Nikitha Susan Saji

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Exploring scalar dark sector with Peceei-Quinn symmetry at the LHC.

Date

2024-07-05

Speaker

Dr. Anupam Ghosh

Venue

Room no: 469 (Main Campus)

Abstract

The Inert Higgs Doublet model (IDM), assisted by Peccei-Quinn (PQ) symmetry, offers a simple but natural framework of a dark sector that accommodates Weakly Interacting Massive Particle (WIMP) and axion as dark matter components. Spontaneous breaking of $U(1)_{PQ}$ symmetry, which was originally proposed as an elegant solution to the strong charge-parity (CP) problem, also ensures the stability of WIMP through a residual $\mathbb{Z}_2$ symmetry. Interestingly, additional fields necessitated by PQ symmetry further enrich the dark sector. These include a scalar field proprietor for axion DM and a vector-like quark (VLQ) that acts as a portal for the dark sector through Yukawa interactions. Moreover, this combination of the axion and WIMP components satisfies the observed DM relic density and reopens the phenomenologically exciting region of the IDM parameter space where the WIMP mass falls between 100 - 550 GeV. We investigate the model-independent pair production of VLQs exploring this region at the Large Hadron Collider (LHC), incorporating the effects of next-to-leading order (NLO) QCD corrections. After production, each VLQ decays into a top or bottom quark accompanied by an inert scalar, a consequence of the residual $\mathbb{Z}_2$ symmetry. Utilising relevant observables with a leptonic search channel and employing multivariate analysis, we demonstrate the ability of this analysis to exclude a significant portion of the parameter space with an integrated luminosity of 300 $\text{fb}^{-1}$.

The cursed Eukaryotes!

Date

2024-07-02

Speaker

Mr.Janaarthanan P A

Venue

Ground Floor Lecture Hall

Abstract

In spite of early rise of eukaryotic organisms about ~1800 million years ago, their diversification happened only after a billion year later. This retardation in evolution of eukaryotic organisms has been attributed to low atmospheric oxygen abundance and nutrient limited conditions in the oceans of that time. In this talk, I will be discussing the nitrogen isotope dynamics during this period and evaluate its impact on eukaryotic evolution.

A Cauldron of Light: Mars as seen in ultraviolet

Date

2024-07-01

Speaker

Dr. Sonal Jain

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Tremendous new insights into the Martian atmosphere have been achieved in recent years by two ultraviolet spectrographs built at LASP: the Imaging Ultraviolet Spectrograph (IUVS) aboard the Mars Atmospheric and Volatile EvolutioN (MAVEN) mission, and the Emirates Mars Ultraviolet Spectrometer (EMUS) aboard the Emirates Mars Mission (EMM). Both instruments have far exceeded their design goals in science return. This has been accomplished in part through opportunistic and innovative observations, not in the original concept of operations. large quantity of data and provided insights on present-day processes at Mars including dayglow, nightglow, aurora, meteor showers, clouds, and solar-planetary interactions. In this presentation, IÂ will highlight key results obtained by IUVS and EMUS, including (1) mapping of thermosphere composition, structure, and variability, including effects of the global dust storm ; (2) a surprisingly high level of auroral activity of three types; (3) characterizing the dynamics using nightglow. We will present an overview of these results and a discussion of their implications for understanding Mars's atmospheric dynamics and evolution.

Physics Informed Neural Networks

Date

2024-06-27

Speaker

Deepanshu Srivastava, SRF

Venue

Room no: 469 (Main Campus)

Abstract

Principles like symmetry and invariance are ubiquitous in physics and have significantly influenced machine learning. This seminar explores the integration of physics principles into neural networks for solving complex problems. The development of physics-informed neural networks is examined, focusing on algorithms enforced by physics knowledge to facilitate the discovery of new physics. Specifically, the role of equivariance is discussed, highlighting its contribution to model efficiency and interpretability. The seminar concludes with a discussion on leveraging these techniques in high energy physics and potential future advancements. This approach holds promise for significant improvements in both theoretical insights and practical applications within particle physics.

Exploring three-dimensional magnetic nulls in the solar atmosphere: Theory and Simulations

Date

2024-06-26

Speaker

Yogesh Kumar Maurya

Venue

USO Seminar Hall

Abstract

A three-dimensional (3D) magnetic null is a location where the magnetic field is zero. These nulls are abundant and are known to be important magnetic topologies in the solar atmosphere, playing vital roles in phenomena such as magnetic reconnection, jets, and circular ribbon flares. However, the mechanisms behind the generation of 3D nulls in such a dynamic atmosphere are yet to be fully explored. Recent magnetohydrodynamics (MHD) simulations propose that magnetic reconnection is responsible for both generating and annihilating 3D nulls, starting from an idealized magnetic field with a single proper radial null. In this seminar, we will briefly discuss the summary of the above work, highlighting the importance, structure, and properties of 3D nulls. We will further delve into the applications of these understandings to a more realistic scenario, incorporating the field line complexities inherent to a complex active region with thousands of preexisting nulls, and discuss the results. Additionally, we will explore the theme with an initially chaotic magnetic field devoid of any 3D nulls and discuss the results.

Plasma Motion in Sunspots

Date

2024-06-25

Speaker

Prof. Debi Prasad Choudhary

Venue

USO Seminar Hall

Abstract

In this talk, I shall present the results to determine three dimensional thermal, magnetic and flow structure of sunspots using spectropolarimetric diagnostic in multiple spectral lines. We have used the observations with the spectropolarimeters at the focal plane of the Dunn Solar Telescope and analysis tools such as inversion codes and magnetic field extrapolation techniques developed by our group. In a series of investigations, we determine the detailed properties of Inverse Evershed Flow. Our results show that these flows are aligned along magnetic field lines that connect the outer penumbra with the outer end of the moat cell in the form of arched loops. We find that there is a positive field strength difference and the negative temperature difference between the inner and outer end point connected by these magnetic arches. This pressure difference induces a flow towards the sunspot following the siphon flow principle, which is in quantitative agreement of the observed flow speeds and those predicted from the pressure balance equation. I shall also introduce the ongoing and future research goals of our group. We are developing an analysis package for spectropolarimetric observations for the following purpose. 1. Develop and apply LTE and NLTE inversion codes to extract stratifications of temperature, velocity and magnetic field structure using multiple chromospheric and photospheric lines. 2. Develop an analysis tool for observations of the Halpha line. 3. Develop an automatic technique for integrating the piecewise continuous results of the H, He I at 1083 nm, and other lines into the analysis for a physically consistent stratification. 4. Determine magnetic and thermal atmospheric properties of sunspots for a full characterization of the solar atmospheric structure and its temporal evolution.

Radiocarbon in soil organic carbon and soil CO2 in a semi-arid tropical region of western India: implications to tropical soil carbon dynamics

Date

2024-06-25

Speaker

Mr. Ranjan Mohanty

Venue

Ground Floor Lecture hall

Abstract

The exchange flux between the soil and the atmosphere is the largest carbon flux (~110×1015 g/yr) making it one of the most important components of global climate change on decadal to century scales. Therefore, it is very important to understand the dynamics of carbon in soil as a slight imbalance in the flux can drastically change the climate. We measured radiocarbon in soil organic matter and soil CO2 to estimate SOC turnover time and sources of CO2 in soils in forests and agricultural lands of Gujarat to assess the role of climatic conditions on SOC turnover time and identify major contributors responsible for CO2 emission from the soil. Results indicate that SOC contents and turnover times in tropical semi-arid soils are significantly influenced by precipitation, vegetation density and land use changes which I will discuss in this talk.

Design and Development of Processing Electonics for Dust EXperiment On-board POEM-3

Date

2024-06-21

Speaker

Ms. Rashmi

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

ust is a major constituent in any planetary system and it is found everywhere in the solar system. Dust EXperiment (DEX), an Impact Ionization Dust Detector, is being developed for detection of these dust particles. DEX was recently flown in PS4 Orbital Experimental Module (POEM-3) of PSLV-C58, launched on 01 January 2024. POEM is the spent PS4 stage (fourth stage of PSLV) to carry out in-orbit scientific experiments for an extended duration. In this seminar, the speaker will discuss the design and development of the Processing Electronics of DEX. Also, the communication protocol (RS485) used in POEM will be discussed.

Probing the Physics of Radiation and Particles Emitted During Energetically-Rich Solar Flares

Date

2024-06-21

Speaker

Dr. Arun Kumar Awasthi

Venue

USO Seminar Hall

Abstract

Solar flares are one of the earliest observational signature of solar eruptions. Although the X-class flares are the largest in intensity class, weak (micro/nano) flares are more frequent, making them a suitable candidate for coronal heating. By reconciling multi-wavelength observations, the standard flare energy release scheme to put forth the physical mechanism responsible for the production of emission and charged particles during flares. However, this scheme is often challenged by the observations, particularly during weak flares. Essentially, it is yet to be understood if the weak flares are just a scaled down version of large flares in the sense of physical processes. In this context, I will provide an overview of the research investigation conducted by us revealing the role of weak flares as unique tracers of pre-eruptive plasma and magnetic field environment. I will also provide an overview of future plans associating the physics of solar flares with the initiation mechanism of the coronal mass ejections with an emphasis on combining the observations from the ADITYA-L1 and the Solar orbiter missions.

Relativistic hydrodynamics and its applications in heavy-ion collisions

Date

2024-06-20

Speaker

Dr. Chandrodoy Chattopadhyay,

Venue

Online---https://imeet.vconsol.com/join/3016457289?be_auth=MzgwMTgw

Abstract

Relativistic heavy-ion collisions at LHC, CERN and RHIC, BNL produce a novel state of matter, the quark-gluon plasma (QGP), where the fundamental constituents of nucleons, i.e., quarks and gluons, become deconfined over nuclear volumes. Understanding the thermodynamic and transport properties of QGP constitute one of the major goals of high energy nuclear physics. Research over the last two decades has established that the bulk evolution of QGP can be remarkably well-described by relativistic hydrodynamics. Although it is traditionally believed that hydrodynamics is applicable only for nearly-equilibrated systems, recent discoveries reveal that it may be successful even for far-off-equilibrium stages of heavy-ion collisions. This leads to a fundamental question pertaining to many-body dynamics: when does a macroscopic system depict hydrodynamic behavior? In this talk I shall present modern formulations of hydrodynamics and use the concept of `non-equilibrium attractors’ to discuss why such formulations are unreasonably effective beyond their expected domain of applicability. I will then present `maximum-entropy hydrodynamics’, a macroscopic theory which can describe both near and far-off-equilibrium regimes of heavy-ion collisions in a single framework. Finally, I will discuss formulations of stochastic hydrodynamics and its extensions to model the evolution of critical fluctuations in a system that is close to a critical point.

Precision in Motion: Fabry-Perot Etalon as a Wavelength Calibrator for Extreme Precision Radial Velocity Methods

Date

2024-06-20

Speaker

Shubhendra Nath Das

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

To date, over 5500 exoplanets have been observed, with the radial velocity method, utilizing Doppler shifts in light, proving its effectiveness. Advancements in spectrograph technology now enable us to detect and analyze subtle Doppler signals, potentially leading to the discovery of Earth-like exoplanets. However, challenges remain, particularly in wavelength calibration techniques. To address this, we propose a new approach utilizing Fabry-Perot etalons (FPE) in conjunction with PRL's cutting-edge spectrograph, PARAS-2. In this presentation, we will discuss recent advancements, including calculations regarding pressure and temperature stability, and showcase the design of the optomechanical assembly for the FPE.

Deformation of the Gruithuisen Region Lava Tube under Compressional Stress on the Moon

Date

2024-06-14

Speaker

Ms Kimi Khungree Basumatary

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Lunar lava tubes have gained considerable attention due to their potential as habitable spaces for future missions. These naturally occurring tunnels provide a shield against extreme temperature variations, radiation, and micrometeorite impacts, making them attractive candidates for potential human bases. One unique lava tube is located in the Gruithuisen region (~35°E, 44°W) on the Moon, characterised by a series of collapsed pits and raised formations. Morphometric analysis reveals eight distinct morphologies, ranging from curvilinear channels to elliptical shapes, while the existence of wrinkle ridges in the study area indicates that the area is subjected to compressive stress. This study employs numerical simulations to investigate how a lava tube responds to compressional stress. The results closely replicate the deformations observed in the Gruithuisen region lava tube, emphasising the significant role of compressional stress in its deformation. These models suggest that the eight unique features result from variations in displacement magnitude and direction along three axes (X, Y, and Z). Our research sheds light on the structural changes in lava tubes under varying compressional stress, enhancing our understanding of how the interplay between tectonic activity and the lava tube has shaped the Moon's surface. In this seminar, I will discuss the importance of this study, the challenges faced during the simulation, and the detailed outcomes.

Origin of granitoids from the Chitradurga greenstone belt: Constraints from geochemical modelling

Date

2024-06-13

Speaker

Dr. Sibin Sebastian

Venue

Online

Abstract

The Chitradurga greenstone belt was intruded by potassic granite and low-K trondhjemite during the Neoarchean. Understanding their origin has implications on reworking of crust and stabilization of the western Dharwar craton. Geochemical and Nd isotopic data suggest partial reworking of different pre-existing crustal lithology. Tonalite-Trondhjemite-Granodiorite (TTG) gneisses represent the most abundant lithology and basement rocks of the craton. Partial melting of TTG gneisses and differentiation of melt resulted in compositionally different potassic granite. Simultaneously, partial melting of metabasites resulted in the formation of trondhjemite. The extent of melting and differentiation are quantified through numerical modelling. Quantitative modelling attests low temperature melting of crustal rocks at different depths and the modification of melt by fractional crystallization during ascent for the formation of the studied rock types. Such reworking event was likely triggered by mafic underplating and H2O dominated fluid flux.

Discovery and Characterization of a Dense Sub-Saturn TOI-6651b

Date

2024-06-10

Speaker

Sanjay Baliwal

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The sub-Saturn classification of exoplanets refers to planets larger than Neptune but smaller than Saturn, typically falling within the range of 4-8 Earth radii. Sub-Saturns are considered failed gas giants with equally massive cores but significantly smaller total masses, having accreted envelopes that are much less than their cores. The absence of these planets in our solar system highlights the variety of possible planetary systems, and studying them around other stars provides valuable insights into this diversity. In this talk, I will discuss our recent discovery of a sub-Saturn TOI-6651b using PARAS-2 spectroscopic observations. TOI-6651b is transiting around a sub-giant, metal-rich G-type star in a ~5.06 day orbit. Joint fitting of the radial velocities from PARAS-2 and transit photometric data from TESS revealed planetary mass of ~59.4 Earth masses and a radius of ~5.30 Earth radii. TOI-6651b has a bulk density of ~2.18 g cm-³, positioning it among the select few known dense sub-Saturns and notably the densest among those detected with TESS. We find that a considerable portion ~85% of the planet's mass consists of dense materials such as rock/iron in the core, while the remaining mass comprises a low-density envelope of H/He. The existence of TOI-6651b challenges conventional planet formation theories and could be a result of merging events or significant atmospheric mass loss through tidal heating.

SMEFT analysis of charged lepton flavor violating B-meson decays

Date

2024-06-10

Speaker

Dr. N Rajeev

Venue

Online---https://imeet.vconsol.com/join/6642133707?be_auth=Mjc4NjM0

Abstract

Charged lepton flavor violation (cLFV) processes, potentially important for various Beyond the Standard Model Physics scenarios are analyzed in the Standard Model Effective Field Theory (SMEFT) framework. We consider the most relevant 2 quark-2 lepton (2q2ℓ) operators for the leptonic and semi-leptonic LFV B-decay (LFVBD) processes Bs → µ +e −, B+ → K+µ +e −, B0 → K∗0µ +e −, and Bs → ϕµ−e +. We analyse the interplay among the Wilson coefficients responsible for these LFVBDs and other cLFV processes like CR(µ → e), ℓi → ℓjγ, ℓi → ℓj ℓkℓm and Z → ℓiℓj, to find the maximal possible LFV effects in B-meson decays. We probe the scale of new physics in relation to the constraints imposed by both classes of the LFV decays while considering both the present bounds and future expectations. In view of the proposed experiments at LHCb-II and Belle II to study charged LFV processes, we have also provided the upper limits on the indirect constraints on such LFVBDs. For the processes where B meson is decaying to µ ± and e ∓, we show that new physics can be constrained by an enhancement of 2-4 orders of magnitude on the current sensitivities of the BRs of B+ → K+µ +e −, B0 → K∗0µ +e −and Bs → ϕµ±e ∓.

Unravelling Mar’s Magmatic Past: Insights from Martian Shergottites

Date

2024-06-07

Speaker

Ms Varsha M Nair

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Shergottites, constituting around 90% of the Martian meteorite collection, are categorized based on texture and mineralogy into various types, including basaltic, olivine-phyric, poikilitic, and gabbroic. Notably, poikilitic shergottites exhibit a distinctive bimodal texture, providing insights into their evolutionary trajectory, marked by an initial slow-cooling poikilitic stage followed by a rapidly cooled interstitial stage. Given their potential abundance in the Martian crust, these meteorites are crucial in studying Martian magmatism. This study delves into the mineralogy, petrology, and olivine-hosted melt inclusions of two poikilitic shergottites, NWA 7397 (enriched) and NWA 1950 (intermediate).

Understanding the Role of magnetic fields in the G47 filamentary cloud

Date

2024-06-06

Speaker

Omkar Jadhav

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Several observational studies have shown that filaments are active sites of star-formation which makes them ideal laboratories to study the physical processes involved. However, star-formation remains a highly complex process, which is driven by an interplay between gravity, turbulence, magnetic fields, and stellar feedback. Among these, the exact role of magnetic fields in the process of star-formation and its interplay with other factors is the least understood. In this talk I will try to address two main questions: What role do magnetic fields play in the star formation process in filaments? How does stellar feedback affects the morphology of magnetic fields in filaments? Subsequently, I will present findings from our ongoing research on the factors responsible for driving the star-formation in the G47 filamentary cloud.

Mathematical tales of blackhole, gravity and machine learning

Date

2024-06-06

Speaker

Dr. Arghya Chattopadhyay

Venue

Online---https://imeet.vconsol.com/join/9420300322?be_auth=MTQzNjAy

Abstract

The aim of this talk is to elaborate on the key concepts of my current research and to outline my future research plans during and beyond the Ramanujan fellowship. I will begin by explaining the basics of quantum complexity with simple examples, followed by an intriguing relationship between the algebra of triple systems and the entropy of black holes in 5 and 4 dimensions. Following this, I will discuss our recent observations in these fields, highlighting notable findings and their implications. Next, I will delve into the bare essentials of machine learning (ML), motivating how principles from physics can enhance ML algorithms. This will be followed by an overview of the two avenues of my research plan: theoretical development and machine learning. I will conclude with a brief discussion on the potential impact and future scope of the proposed research plan for Ramanujan Fellowship.

On the Response of Transition Region and Corona to Rapid Excursions in the Chromosphere

Date

2024-06-04

Speaker

Mr. Ravi Chaurasiya

Venue

USO Seminar Hall

Abstract

Spicules are the thin, hair/grass-like structures that are prominently observed at the chromospheric solar limb. It is believed that fibrils and Rapid Blue and Red Excursions (RBEs and RREs; collectively referred to as REs) correspond to on-disk counterparts of type I spicules & type II spicules, respectively. Our investigation focuses on observing the response of these REs alongside similar spectral features in the chromosphere, transition Region (TR), and corona, utilizing space-time plots derived from co-ordinated observations from SST/H&#945;, IRIS, and SDO. Our analysis reveals upflowing REs, promptly reaching temperatures characteristic of the TR and corona, indicating a multi-thermal nature. Similarly, downflowing features exhibiting similar spectral signatures over the disk display plasma motion from the corona to chromospheric temperatures, demonstrating a multithermal nature. In addition to distinct upflows and downflows, we observe sequential upflow and downflow along the same path, depicting a distinctive parabolic trajectory in space-time plots of observations sampling TR and various coronal passbands. Similar to isolated upflows and downflows, these REs also exhibit a multi-thermal nature throughout their trajectory. Furthermore, our results reveal a more intricate motion of the REs in which both upflow and downflow coexist at the same spatial location. On a different note, our analysis, utilizing coordinated IRIS spectral observations, shows spatio-temporal redshifts/downflows in both the TR and chromosphere due to the upper atmosphere flow of plasma in the form of bundles of spicules or features exhibiting similar spectra. Our analysis suggests that at least subsets of the strong redshifts/downflows observed in TR temperature spectra are due to these bundles of spicules or features exhibiting similar spectra.

Deciphering the Mysteries of the Long-Lived Particles at the colliders

Date

2024-06-03

Speaker

Ms. Chandrima Sen

Venue

Online--- https://imeet.vconsol.com/join/4524798341?be_auth=OTExNTQ0

Abstract

Conventional searches at the LHC operate under the assumption that Beyond the Standard Model particles undergo immediate decay upon production. However, this assumption lacks inherent a priori justification. This talk delves into the exploration of displaced decay signatures across various collider experiments. Combining insights from several studies, we show how small Yukawa couplings, compressed mass spectra, and collider boosts lead to distinctive displaced decays, observable at the CMS, ATLAS and proposed future detectors. These phenomena, manifesting within both Type-I and Type-III seesaw mechanisms, and the Vector-like lepton model with non-zero hypercharge, provide a unique insight into the behaviors of neutrinos and dark matter. The seminar highlights the technical challenges and breakthroughs in detecting and interpreting these signatures, emphasizing their significance in probing the depths of the extensions of the Standard Model.

CHALLENGES INVOLVED IN THE DEVELOPMENT OF X-RAY ASTRONOMY TELESCOPES

Date

2024-05-30

Speaker

Neeraj K. Tiwari

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The advancement in X-ray astronomy is directly linked to the high-sensitivity observations primarily provided by X-ray telescopes. The fundamental parameters of X-ray telescopes, such as effective area, angular resolution, field of view, and energy response, define observational sensitivity. Significant improvement has been achieved in these parameters over the past few decades. However, further enhancement from a basic design perspective is constrained by the fact that X-ray reflection occurs only at grazing incident angles. This limitation leaves only the option for further improvement by reducing the geometrical uncertainty associated with X-ray mirrors. In this talk, I will discuss the role of X-ray telescopes in X-ray astronomy, their working principles, the possibility of improvement through design, various fabrication methods, metrology, along with their limitations.

Insights into the major sources and formation pathways of p-NO3- using dual isotope proxy

Date

2024-05-30

Speaker

Ms. Chandrima Shaw

Venue

Ground Floor Lecture Hall

Abstract

NOx plays a significant role in atmospheric chemistry, influencing air quality, human health, climate change. It contributes to the formation of particulate matter (p-NO3-), tropospheric ozone, acid rain, and smog, while also serving as a nutrient for both oceanic and terrestrial ecosystems. Despite its significant role, the sources of NOx and its conversion pathways to p-NO3- remain poorly understood both globally and regionally (South-East Asia). Dual isotopes (δ18O and δ15N) of p-NO3- can serve as a powerful tool to understand the formation pathways of p-NO3- and sources of NOx. In this talk I will discuss the application of dual isotopes (δ18O and δ15N) of p-NO3- in understanding the atmospheric chemistry and sources related to p-NO3- and NOx

On the nature of Hub-Filament Systems in Galactic "Snake" IRDC G11.11-0.12

Date

2024-05-28

Speaker

Dr. Naval Kishor Bhadari

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Hub-Filament Systems (HFSs) are complex, web-like structures of filaments within molecular clouds and are widely known as nurseries for massive stars. While there is evidence of mass transfer from the molecular clouds to the hub through filaments, the exact driving factors of this process remain poorly understood. In this talk, I will review the current understanding of HFSs and present the findings from our ongoing work on the Galactic 'Snake' IRDC G11.11-0.12, which is known to host multiple HFSs. I will conclude by discussing how HFSs act as efficient material collection systems, ultimately favouring the formation of star clusters, including massive stars.

On the Response of Transition Region and Corona to Rapid Excursions in the Chromosphere

Date

2024-05-27

Speaker

Mr. Ravi Chaurasiya

Venue

USO Seminar Hall

Abstract

Spicules are the thin, hair/grass-like structures that are prominently observed at the chromospheric solar limb. It is believed that fibrils and Rapid Blue and Red Excursions (RBEs and RREs; collectively referred to as REs) correspond to on-disk counterparts of type I & type II spicules, respectively. Our investigation focuses on observing the response of these REs alongside similar spectral features in the chromosphere, transition Region (TR), and corona, utilizing space-time plots derived from co-ordinated observations from SST/H-alpha, IRIS, and SDO. Our analysis reveals upflowing REs, promptly reaching temperatures characteristic of the TR and corona, indicating a multi-thermal nature. Similarly, downflowing features exhibiting similar spectral signatures over the disk display plasma motion from the corona to chromospheric temperatures, demonstrating a multithermal nature. In addition to distinct upflows and downflows, we observe sequential upflow and downflow along the same path, depicting a distinctive parabolic trajectory in space-time plots of observations sampling TR and various coronal passbands. Similar to isolated upflows and downflows, these REs also exhibit a multi-thermal nature throughout their trajectory. Furthermore, our results reveal a more intricate motion of the REs in which both upflow and downflow coexist at the same spatial location. On a different note, our analysis, utilizing coordinated IRIS spectral observations, shows spatio-temporal redshifts/downflows in both the TR and chromosphere due to the upper atmosphere flow of plasma in the form of bundles of spicules or features exhibiting similar spectra. Our analysis suggests that at least subsets of the strong redshifts/downflows observed in TR temperature spectra are due to these bundles of spicules or features exhibiting similar spectra.

Analysis of surface temperatures obtained from Chandrayaan-2 Imaging Infra-Red Spectroscopy (IIRS) data and comparison with LRO-Diviner data

Date

2024-05-24

Speaker

Dr. Subhadyouti Bose

Venue

SEMINAR ROOM NO # 113/114 (THALTEJ CAMPUS)

Abstract

Imaging Infra-Red Spectrometer (IIRS), launched onboard Chandrayaan-2 on July 2019, is an advanced hyperspectral spectrometer that captures high-resolution images of the lunar surface at a spatial resolution of 80 m/pixel with a high spectral resolution of 20 nm. The spectral range of IIRS extends from 0.7 µm to 5 µm and includes 250 spectral bands. Calibrated IIRS radiance data have been used to estimate surface temperatures at different locations on the Moon. In this study, I will present results obtained from IIRS data as well as discuss results from a comparative analysis with LRO-Diviner as well as Chandrayaan-1 Moon Mineralogy Mapper (M3) data.

Propagation and damping of slow magnetoacoustic waves from photosphere to corona along the fan loops rooted in sunspot umbra

Date

2024-05-21

Speaker

Ms. Ananya Rawat

Venue

USO Seminar Hall

Abstract

Coronal fan loops rooted in sunspot umbra constantly show propagating slow magnetoacoustic waves (SMAWs) of various periods in the corona. However, the origin of these waves found along the whole umbral atmosphere is still unclear. Here, we studied these waves along a clean fan loop system using multi-wavelength imaging and spectroscopic observations from SDO and IRIS. We traced the origin of 3-min waves at the photosphere by utilizing amplitude and frequency modulations of 3-min waves from the corona to the photosphere. This loop tracing also provides the first observational evidence of loop area divergence with height in the umbral atmosphere. We calculated the energy flux of these waves with height in the umbral atmosphere and further obtained the damping lengths of SMAWs propagating along the fan loops to be approx. 208 km and 170 km for 3-min and 1.5-min periods respectively. To investigate the role of area expansion on the damping of these SMAWs, we calculated the total wave energy content within the loop cross-sectional area at each atmospheric height. We further deduced the damping lengths of total wave energy content to be approx. 303 km and 172 km for 3-min and 1.5-min period waves respectively, and thus present the actual damping of SMAWs after taking into account the geometric effect of area expansion of the loops. Our finding highlights the role of loop expansion and frequencies in the damping of SMAWs from the photosphere to corona along fan loops.

Scientific computing with open source: An in-house developed Software for PRL-AURiS Data Exploration

Date

2024-05-21

Speaker

Ms. Pratheeksha Nayak

Venue

Ground Floor Lecture Hall

Abstract

Use of open source tools can play a pivotal role in scientific computing by providing robust, flexible solutions for various data analysis tasks. Python, with its extensive libraries and frameworks, is particularly well-suited for scientific computing. SPADE (Software for PRL-AURiS Data Exploration) is a web application developed using Python to enable computation of radiocarbon age estimates using the raw data from the 1 MV Accelerator Mass Spectrometer(AMS) at PRL. It is the first step in the development of a software suite for various data treatment and analysis protocols that can be implemented on data obtained from AMS. SPADE has an interactive interface and can be deployed anywhere without the need to install Python or any of its packages. In this talk, I shall discuss the nature of the raw data, workflow of the data processing pipeline, the details of implementation and the future objectives of SPADE.

Physical and Chemical Properties of Stratospheric Aerosols using Balloon Borne Instruments

Date

2024-05-14

Speaker

Dr. Gwenael Berthet

Venue

Online

Abstract

Aerosol particles of the stratosphere are key components of the Earth’s radiative balance and of the processes controlling the ozone layer. They have various sources, both of anthropogenic and natural origin, more or less sporadic like volcanic eruptions and intense wildfires. We will present an overview of the knowledge of stratospheric aerosols regarding their chemical and physical properties with a specific focus on in situ observations from balloon-borne instruments (optical particle counters, backscatter sondes, aerosol collectors) launched from various locations on the globe. These measurements, together with space-borne observations and chemistry-transport model simulations, show particles of different sizes and types like sulphuric acid droplets, organics, nitrates, meteoric material with proportions dependent on seasons and regions. Specifically, we will show results from balloon campaigns (called BATAL) conducted by TiFR in India from Hyderabad.

Exploring Reconnection in Data-Based MHD Simulations of Solar Flares

Date

2024-05-13

Speaker

Mr. Satyam Agarwal

Venue

USO Seminar Hall

Abstract

Solar flares are believed to be the manifestation of magnetic reconnection, dissipating magnetic energy in the form of heat, kinetic energy of plasma, and particle acceleration. As a result, the net magnetic energy of the magnetofluid decreases. Further, reconnection changes connectivity of magnetic field lines with respect to the plasma parcels, causing a topological reconfiguration. To explore reconnection and its implications, we perform data-based MHD simulations of flares. In this regard, notable is the use of magnetic field extrapolation for modeling the magnetic field in active-regions. The extrapolated field is utilized as an initial condition for the MHD simulation. In the presence of two contemporary models, namely the nonlinear force-free field (NLFFF) and non force-free field (NFFF), it is imperative to explore the effect of these two varying models on reconnection and consequently on the simulated dynamics of flares. Further, owing to decrease of magnetic energy during flares, the magnetofluid is expected to relax toward an equilibrium of lower energy. Consequently, the simulated dynamics merits interest from the perspective of MHD relaxation theory also. Toward such explorations, we investigate the data-based simulation of solar flares and in this seminar, I will be discussing the results of these studies.

High precision Al-Mg isochron of calcium Aluminium Rich Inclusions from IMS-1280

Date

2024-05-10

Speaker

Ankit Prakash Singh

Venue

SEMINAR ROOM NO # 113/114 (THALTEJ CAMPUS)

Abstract

Calcium Aluminium rich Inclusions are one of the first formed solids of our solar system ~4568.7 myr. It is suggested that 26Al, an SLR (which decays into 26Mg) with a half-life of 0.717 Myr, was homogenously distributed throughout in the solar system. For this reason, the initial abundance of 26Al is widely used to determine the relative chronology of the early solar system. Using the Al-Mg systematics, the primitive CAIs are identified which will be further analyzed for Ca-K systematics. In this talk, I will present the high-precision SIMS data obtained for Al-Mg systematics from IMS 1280 at CRPG, Nancy. Further, I will talk about the Ca-K systematics and standard run that was done at high mass resolution to remove the isobaric interferences. The dataset obtained from the standard run resulted in the deliberation and preparation of new synthetic standards of refractory minerals of varying Ca/K ratios.

Impact of mass transfer rate on the behaviour of cataclysmics

Date

2024-05-09

Speaker

Aakash

Venue

Seminar Room #113/114 (Thaltej Campus)

Abstract

The transfer of mass between the two stellar components via an accretion disc, a characteristic of cataclysmic variables (CVs), gives rise to various intriguing astrophysical phenomena such as nova, dwarf nova, etc. It appears that the rate at which this transfer of mass takes place plays a significant role in the dwarf nova cycle and the behaviour of cataclysmics in general. Depending on it, a CV may show characteristics of a dwarf nova with semi-regular outbursts or a novalike variable. The canonical evolution model of cataclysmics suggests that different mechanisms are responsible for driving the mass transfer above and below the period gap (2 hr ≲ Porb ≲ 3 hr). However, the reduction and enhancement in the mass transfer rate (e.g. novalikes) and the underlying causes are still not understood well. In this talk, I will discuss the response of a cataclysmic system to different mass transfer rates. I will also present the calculation of mass transfer rate for the long period dwarf nova system V1948 Cyg and discuss how the results accord with the disc instability model.

Impact-induced textures and phase transformations in shocked Indian meteorites.

Date

2024-05-03

Speaker

Dr. Kishan Tiwari

Venue

ROOM NO 113 (THALTEJ CAMPUS)

Abstract

Hyper-velocity impact between planetary bodies induces high-pressure and high-temperature conditions triggering polymorphic transformation within the impacted materials. Moreover, such impacts lead to the fragmentation of the impactor with fragments dislodged in all directions. Some of these fragments eventually fall on Earth as shocked meteorites. Here, I will present my analysis of shocked Indian meteorites. I will discuss different high-pressure phases and shock-induced textures present in these meteorites and their formation conditions.

Atmospheric Water Vapor Dynamics at Guru Shikhar, Mt. Abu, the highest point of the Aravalli Range, Rajasthan

Date

2024-04-30

Speaker

Mr. Virendra R. Padhya

Venue

Ground Floor Lecture Hall

Abstract

The stable isotope ratios (δ18O and δD) of water vapor are used to characterize continuous variations in large-scale and boundary-layer atmospheric processes. We carried out continuous measurements of δ18O and δD in Ground level water vapor at Gurushikhar, Mount Abu, Rajasthan, from Feb 2023 to Feb 2024 to understand how large-scale and local atmospheric processes influence variations in water vapor δ18O and δD on daily to seasonal time scales. Most of the variabilities are associated with the transition between the Indian summer monsoon and the westerlies, which transport distinct moisture to the study area. The local temperature, specific humidity and boundary layer height impact the diurnal variations in water vapor δ18O. The data reveal interesting seasonal and diurnal atmospheric phenomena which will be discussed in the talk.

Enhancing Geological Insights: Information-Theoretic Analysis of REE Concentrations for Rock Discrimination and Source Provenance Studies

Date

2024-04-23

Speaker

Mr. Shivansh Verma

Venue

NanoSims Hall

Abstract

In the past decade, the application of information-theoretic methods has substantially enhanced our understanding of intricate complex processes. In this talk, I will discuss one such method based on Kullback-Leibler (KL) divergence, which utilizes Rare Earth Elements (REEs) concentrations to identify the similarities and differences among co-existing rocks of any given complex. In case of igneous rocks, the order of KL-divergence effectively distinguishes between rocks that have undergone different degrees of physical differentiation during their genesis. Moreover, when employed in conjunction with isotopic data, the method can yield robust constraints for source provenance studies in the context of sedimentary rocks. I will also discuss the differences between the KL-divergence method and Principal Component Analysis (PCA), highlighting the unique information provided by the former

The Highlights Of 55th Lunar And Planetary Science Conference (LPSC-2024)

Date

2024-04-19

Speaker

Mr. Trinesh Sana & Dr. Subham Sarkar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Mr. Trinesh Sana and Dr. Subham Sarkar attended the 55th Lunar and Planetary Science Conference (LPSC-2024) held from 11th to 15th March 2024 at the Woodlands, Houston, Texas, United States of America. This conference brings together international specialists in petrology, geochemistry, geophysics, geology, and astronomy to present the latest research results in planetary science. The conference is organized jointly by the Lunar and Planetary Institute and NASA. The meeting provides a unique opportunity for scientists from around the world to talk about the latest results of their research and current planetary science missions. Trinesh presented his recent work regarding Dust Charging Within Lunar Photoelectron Sheath. Subham delivered a talk about the maiden detection of Natrolite on Mars using Perseverance Rover Data. Apart from presenting in their own sessions, they have attended various other sessions covering topics to their interests. In this seminar, these two young researchers will share their experiences and knowledge gathered from the conference.

New Ways to Detect Light Dark Matter

Date

2024-04-19

Speaker

Dr. Anirban Das

Venue

Room no: 469 (Main Campus)

Abstract

In the last few years, direct detection of light sub-GeV dark matter has emerged as a frontier research area. Because of its low energy scales, many condensed matter systems have been proposed as possible target materials. In this talk, I'll briefly review the mechanisms behind a few of them, and introduce two novel ideas. First, to use superconducting quantum devices to measure the power deposition from dark matter scattering. I'll show that the existing data already put competitive limits on the dark matter-nucleon interaction. I'll also describe how bilayer graphene with voltage-tunable band gap can be used to probe sub-MeV dark matter-electron scattering with promising future prospects.

Dark Matter: the Enigma of our Cosmos

Date

2024-04-18

Speaker

Dr. Anirban Das

Venue

Room no: 469 (Main Campus)

Abstract

We have known about the existence of a dark sector in our Universe for almost 100 years that comprises about 85% of all matter. However, we are still in the dark about its fundamental nature. In this talk, I will describe various evidences of dark matter that we have, and outline a few theoretical ideas to explain its cosmic abundance. Finally, I will give an overview of various experimental endeavors to identify it, such as direct, indirect detection experiments etc.

Daksha: Indian Eyes on Transient Skies

Date

2024-04-15

Speaker

Prof. Varun Bhalera

Venue

Seminar Room #113/114 (Thaltej Campus)

Abstract

Daksha is a proposed High Energy transients mission that will have higher sensitivity than any other mission in the world. Daksha will comprise of two satellites covering the entire sky from 1 keV to > 1 MeV. The primary objectives of the mission are to discover and characterize electromagnetic counterparts to gravitational wave sources; and to study Gamma Ray Bursts (GRBs). With its broadband spectral response, high sensitivity, and continuous all-sky coverage, it will discover fainter and rarer sources than any other existing or proposed mission. Daksha can make key strides in GRB research with polarization studies, prompt soft spectroscopy, and fine time-resolved spectral studies. In addition, Daksha is a versatile all-sky monitor that can address a wide variety of science cases. Daksha will provide continuous monitoring of X-ray pulsars. It will detect magnetar outbursts and high energy counterparts to Fast Radio Bursts. Using Earth occultation to measure source fluxes, the two satellites together will obtain daily flux measurements of bright hard X-ray sources including active galactic nuclei, X-ray binaries, and slow transients like Novae. Correlation studies between the two satellites can be used to probe primordial black holes through lensing. Daksha will have a set of detectors continuously pointing towards the Sun, providing excellent hard X-ray monitoring data. Closer to home, the high sensitivity and time resolution of Daksha can be leveraged for the characterization of Terrestrial Gamma-ray Flashes. In this talk, I will discuss the scientific impact of Daksha in all these areas

Cloud-Cloud Collision: Formation of Hub-Filament Systems and Associated Gas Kinematics

Date

2024-04-12

Speaker

Arup Kumar Maity

Venue

Seminar Room #113/114 (Thaltej Campus)

Abstract

Massive star-forming regions (MSFRs) are commonly associated with hub-filament systems (HFSs) and sites of cloud-cloud collision (CCC). Recent observational studies of some MSFRs suggest a possible connection between CCC and the formation of HFSs. To understand this connection, we analyzed the magneto-hydrodynamic simulation data from Inoue et al. (2018). This simulation involves the collision of a spherical molecular cloud with a plane-parallel sea of dense molecular gas at a relative velocity of about 10 km/s. Following the collision, turbulent and non-uniform cloud undergoes shock compression, rapidly developing filamentary structures within the compressed layer. We found that CCC can lead to the formation of HFSs, which is a combined effect of turbulence, shock compression, magnetic fields, and gravity. The collision between the cloud components shapes the filaments into a cone and drives inward flows among them. These inward flows merge at the vertex of the cone, rapidly accumulating high-density gas, which can lead to the formation of massive star(s). The gas distribution in the position-velocity and position-position spaces highlights the challenges in detecting two cloud components and confirming their complementary distribution if the colliding clouds have a large size difference. However, such CCC events can be confirmed by the position-velocity diagrams presenting gas flow toward the vertex of the cone, which hosts gravitationally collapsing high-density objects, and by the magnetic field morphology curved toward the direction of collision. In this talk, I will present these initial results.

Dancing Lunar Dust

Date

2024-04-12

Speaker

Mr. Trinesh Sana

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Lunar Horizontal Glow, observed during the Surveyors and Apollo missions, unveiled the intricate dynamics of lunar dust movement. The movement of lunar dust, akin to "dancing," is primarily driven by electrostatic forces generated by the continual bombardment of charged particles from the solar wind and highly energetic UV photons on the lunar surface and dust particles. This celestial choreography is important for unravelling the fundamental processes governing surface evolution not only on the Moon but also across other airless bodies throughout the solar system.

Solar Wind Ion Spectrometer (SWIS), A miniature mass spectrometer onboard the Aditya-L1 mission: Objectives, Configuration, and Development

Date

2024-04-09

Speaker

Mr. Pranav Adhyaru

Venue

NanoSims Hall

Abstract

The Solar Wind Ion Spectrometer (SWIS) is a subsystem of the ASPEX (Aditya Solar Wind Particle Experiment) payload, developed by PRL and one of seven payloads onboard the Aditya-L1 mission. The Aditya-L1 was launched in September 2023 and reached the Sun-Earth system's first Lagrangian point, L1, in January 2024. The primary focus of the ASPEX payload is to understand the Sun and solar wind processes as well as the acceleration and energization of the solar wind particles. ASPEX consists of two subsystems, SWIS and STEPS. The SWIS measures the particles in the energy range from 100 eV to 20 KeV, whereas STEPS works in 20 KeV to 5 MeV. SWIS is a miniature mass spectrometer customized for the space application to understand the origin of solar wind (slow and fast wind) and supra-thermal ions, thermal anisotropy, turbulence, and arrival of ICME (Interplanetary Coronal Mass Ejection) and SIR (Stream Interface Region) at L1 for space weather science and applications. In this seminar, I will highlight the science and technical objectives and configuration of the SWIS experiment. The design and development aspects of the High Voltage Power Supplies and Front-End-Electronics will also be discussed. The SWIS subsystem was switched on in December 2023 during the cruise phase of the Aditya-L1 for the performance verification of all its units. The data acquired during this phase and the preliminary results will also be presented.

Highly Siderophile Elements In Lunar Mantle And Crust Beyond The Procellarum KREEP Terrane

Date

2024-04-05

Speaker

Mr. Yash Srivastava

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Volcanism and collisional impacts are the two primary processes that have shaped the terrestrial bodies of the Solar System. While these geological processes are ubiquitous across planetary bodies, the absence of an atmosphere and minimal active geologic processes (e.g., plate tectonics) on the Moon makes it the prime candidate for understanding these processes over a large timescale (~4.4 – 2.0 Ga). The absolute and relative abundances of the highly siderophile elements (HSE: Re, Os, Ir, Ru, Rh, Pt, Pd, and Au) have long been utilized to understand the volcanic and impact history of the Moon. Most of our current understanding of the abundance of highly siderophile elements (HSE) in the Moon comes from returned samples, which limits our insight. This motivates us to analyze additional samples, particularly those likely sourced away from the Procellarum KREEP Terrane (PKT), to better understand HSE abundance and Re-Os isotope variability in lunar crust and mantle reservoirs. In this talk, I will discuss the HSE and Re-Os isotopic abundance of four lunar meteorites, A-881757, Y-86032, Y 981031, and Y 983885, that are likely sourced away from the PKT region. The unbrecciated lunar meteorite A-881757 provides a key understanding of the HSE abundance in the KREEP-free lunar mantle, while the regolith breccia meteorites Y-86032, Y 981031, and Y 983885 offer us to examine the nature, flux, and composition of the materials striking the unexplored lunar surface away from the PKT. Most importantly, these results will provide a robust constraint on the HSE abundance of the Moon, globally.

Let’s slip into inspiral

Date

2024-04-05

Speaker

Dr. Shilpa Kastha

Venue

Online ---> https://imeet.vconsol.com/join/1736146599?be_auth=NzM2NDU3

Abstract

I will start with a brief introduction to gravitational waves and update about the current detections and my involvement in those. My main focus will be a state-of-the-art discussion on contemporary tests of general relativity with gravitational wave observations and my contributions to developing a few of those.

Optical Monitoring of a long-period dynamically new comet C/2020 V2 (ZTF)

Date

2024-04-04

Speaker

Goldy Ahuja

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Comets are the pristine bodies that retain the essential information of the early Solar System. They are mainly placed in two reservoirs, i.e., Kuiper Belt and Oort Cloud. These reservoirs hold a large number of comets. The comets in the Kuiper belt are responsible for the short-period low-inclination known as Jupiter family comets (JFC), while comets in the Oort Cloud account for the long-period comets with different inclinations (as compared to the JFC). Studying the composition of different classes of comets is essential to understanding the formation and evolution of the Solar System. Dynamically New Comet (DNC) is a subcategory of long-period comets with a semi-major axis > 10000 AU. These comets are entering the inner Solar System for the first time, which gives us an excellent opportunity to study their composition. The Zwicky Transient Facility discovered Comet C/2020 V2 (ZTF) in November 2020. It was categorized as a dynamically new comet. In the talk, I will present the different results of this dynamically new comet C/2020 V2 (ZTF) using the photometric observations from TRAPPIST and spectroscopic observations from different observatories in India.

A geochemical study on the Kali River with emphasis on chemical weathering and anthropogenic impacts, south-western India

Date

2024-04-02

Speaker

Dr. Arun Kumar

Venue

Online

Abstract

Small mountainous rivers (SMRs) in tropical regions are some of the most active sites for chemical weathering and associated CO2 consumption. Studies have revealed the incredibly high rates of chemical weathering in these areas. Geochemical sampling on the Kali River Basin (KRB) revealed that silicate weathering is the major contributor to cation yields, while carbonate weathering has a minor impact. These rates are among the highest reported for granitic-gneiss terrains in SMRs, emphasizing the importance of studying geochemical processes. The pollution effects on the riverine ecosystem are assessed by examining chemical and biological components. The findings of this study have important implications for environmental management and for the development of effective strategies to mitigate human activities' adverse impacts on riverine chemistry and the ecological health of the river and coastal areas.

Gaining insight into radiative and variability phenomena of black hole X-ray binaries

Date

2024-04-02

Speaker

Nazma Husain

Venue

online: https://meet.google.com/jqv-rbwg-unz

Abstract

Around 72 Black Hole X-ray Binary (BHXB) candidates have been discovered till now, showcasing variety of radiative phenomena and rapid variability in the X-ray lightcurve. This variability manifests itself as Quasi-Periodic Oscillations (QPOs) and broadband noise continuum in the power spectra. These properties offer a unique lens to study extreme gravitational environments in close regions to the black hole. Despite substantial research, our understanding of the origin and energy-dependent behaviour of the variability remains incomplete. I will focus on the modelling of variability, testing its different origins and exploring the spectral behaviour in different accretion regimes, using data from AstroSat, NICER, NuSTAR and Swift. In addition, I will discuss a peculiar case of a highly luminous BHXB, which exhibited non-standard disk behaviour. I will conclude by exploring future prospects to better our understanding of the accretion physics around different compact object systems.

Long-term X-ray temporal and spectral study of a Seyfert galaxy Mrk 6

Date

2024-03-28

Speaker

Narendranath Layek

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Active galactic nuclei (AGNs) are the extremely luminous and most persistent energetic sources in the universe, powered by mass accretion onto the supermassive black hole (SMBH) at the centre of its host galaxy. The X-ray emission from AGN is vital to probe the physical processes in extreme gravity as it is thought to originate from a high-temperature electron cloud called the corona or Compton cloud, situated near the black hole. We present a long-term X-ray study of a nearby Active Galactic Nucleus Mrk 6, utilizing observations from XMM-Newton, Suzaku, Swift and NuSTAR observatories, spanning 22 years from 2001 to 2022. Mrk 6 is a relatively unexplored AGN that has exhibited “changing-look” behaviour in optical observations. However, its characteristics in the X-ray band have not been thoroughly investigated. We found a complex correlation between the soft (0.5 − 3.0 keV) and hard (3.0 − 10.0 keV) X-ray light curves. This result prompts a detailed investigation through spectral analysis, employing various phenomenological and physical models on the X-ray spectra. Based on the overall result obtained from X-ray spectroscopy, we found that, although Mrk 6 displays characteristics of a changing-look AGN (CLAGN) from optical observations, our X-ray spectral analysis did not show any significant variation in the X-ray luminosity and Eddington ratio over a period of 22 years. This indicates that in the X-ray regime, the source did not show any change in its behaviour during the observational period. In this talk, I will discuss our findings from temporal and spectral studies of Mrk 6, obtained from the analysis of X-ray data.

Investigating water-rock interaction on Martian crust using nakhlite meteorites

Date

2024-03-22

Speaker

Mr. Aditya Das

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

A hint toward how water-rock interaction occurred on the Martian crust is provided by the Nakhlites due to the clay deposition along the fractures of primary minerals. To gain further insight into the water-rock interaction, multiple Nakhlite meteorites have been obtained throughout the established depth profile to determine whether the alteration of the primary mineral is uniform in all the Nakhlites or varies along the depth profile.

Radiative Fermion Masses and Strong CP

Date

2024-03-22

Speaker

Mr. Gurucharan Mohanta

Venue

Room.No:469 (Main Campus)

Abstract

The hierarchical structure of the Standard Model (SM) charged fermions can be explained by the mechanism of radiative generation of fermion masses. In this mechanism, third-generation fermions are allowed tree-level masses, and lighter fermion masses are induced through loops. Implementation of such mechanisms requires extensions of SM. We will discuss a scenario that can possibly generate fermion masses radiatively and possesses a solution to Strong CP.

Towards the discovery and characterisation of Earth analogs with the PLATO mission

Date

2024-03-21

Speaker

Dr. Alexandre SANTERNE

Venue

Google Meet: https://meet.google.com/wsj-jvrj-ipw

Abstract

PLATO is a mission from the European Space Agency that will be launch in 2026. It aims at discovering and characterising transiting exoplanets, down to Earth-size planets in the habitable zone of their host star (so called, the Earth analogs). Unlike the Kepler mission, the ground-based characterisation of the planet’s mass is fully part of the mission objective and ground-segment design. During this seminar, I will present the PLATO mission, including the most recent news about its development. I will also details what are the plan for the radial-velocity follow-up of the PLATO candidates and the discuss the current limitations.

Implications of very light sterile neutrinos for absolute mass variables

Date

2024-03-21

Speaker

Mr. Debashis Pachhar

Venue

Room.no: 469 (Main Campus)

Abstract

The framework of three-flavor neutrino oscillation is a well-established phenomenon, but results from the short-baseline experiments, such as the Liquid Scintillator Neutrino Detector (LSND) and MiniBooster Neutrino Experiment (MiniBooNE), hint at the potential existence of an additional neutrino state characterized by a mass-squared difference of approximately 1 eV². The new neutrino state is devoid of Standard Model (SM) interactions, commonly referred to as the “sterile neutrino” state. In addition, a sterile neutrino with a mass-squared difference of 10^{-2} eV² has been proposed to improve the tension between the results obtained from the Tokai to Kamioka (T2K) and the NuMI Off-axis ν_e Appearance (NOνA) experiments. The hypothesis of an additional light sterile neutrino state introduces four distinct mass spectra. In this talk, we discuss the implications of the above scenarios for the observables that depend on absolute mass of the neutrinos, namely - the sum of neutrino masses (∑) from cosmology, the effective mass of the electron neutrino from beta decay (mβ), and the effective Majorana mass ( mββ) from neutrinoless double beta decay. We show that, some scenarios can be disfavored by the current constraints of the above variables.

Influence of solar wind medium on the propagation of Earth impacting Coronal Mass Ejections in Heliosphere

Date

2024-03-20

Speaker

Mr. Sandeep Kumar

Venue

USO Seminar Hall

Abstract

Coronal Mass Ejections (CMEs) are subject to changes in their direction of propagation, tilt, and other properties. We investigated 15 Earth-impacting coronal mass ejections (CME) observed during April 2010 to August 2018 in the Heliospheric Imager (Onboard STEREO) field of view (FOV) to study their propagation in the heliosphere. Out of 15 events, approximately 50 % followed self-similar expansion up to approximately 40 R&#8857;. Only two events showed significant rotation in HI FOV. The rest of 50 % events showed deflection either in latitude or longitude. This study suggests that CME rotation is not very common in the heliosphere. Our study emphasizes the importance of considering both the ambient magnetic field and solar wind environment to understand the heliospheric propagation of CMEs. The observed deflections and rotations of CMEs can be attributed to a combination of factors, including their interaction with the ambient solar wind, the influence of the ambient magnetic field, and the favorable conditions in the heliosphere required for rotation. These findings contribute to our understanding of the complex dynamics involved in CME propagation and highlight the need for comprehensive modeling and observational studies to improve space weather predictions.

A Multi-wavelength Study of Magnetic Cataclysmic Variables

Date

2024-03-20

Speaker

Nikita Rawat

Venue

Google Meet: https://meet.google.com/nzs-gife-xpb

Abstract

Magnetic Cataclysmic Variables (MCVs) are a class of semi-detached binary star systems that consist of a white dwarf (WD) and a companion star, typically a Roche-lobe filling late-type main sequence star. The strong magnetic field associated with the WD distinguishes MCVs from other cataclysmic variables. It plays a crucial role in governing the accretion process in these binaries and also decides two distinct classes of MCVs: polars and intermediate polars (IPs). In polars, the magnetic field of the WD is strong enough (typically, in a range of 10-100 MG) to lock the whole system into synchronous (or almost synchronous) rotation. On the other hand, IPs have a weaker magnetic field (<10 MG) due to which they rotate asynchronously. The majority of IPs have the spin period of the WD, roughly one-tenth of the orbital period of the binary system. MCVs exhibit a wide range of timing (periodic and quasi-periodic) and spectral properties, more commonly in optical and X-ray wavelengths. These characteristics serve as valuable tools for unravelling and gaining insights into the intricate accretion processes within these systems. Among the MCVs, the appropriate classification of new sources is also essential to understand these systems thoroughly in terms of their accretion geometry. Further, the variable nature of accretion flow is one of the basic characteristics of an IP and has been observed in only a few IPs. In this talk, I will discuss the various photometric, spectroscopic, and polarimetric characteristics of a diverse sample of such objects in various evolutionary stages with spin-to-orbital period ratios ranging from 0.1 to 1.0 to gain insights into the various accretion flow scenarios these systems manifest.

Geochemical behaviour and cycling of Uranium and Molybdenum in the Ganga (Hooghly) river estuary, India

Date

2024-03-19

Speaker

Dr. Rakesh

Venue

Online

Abstract

The study forms a detailed investigation of sources and processes involved in the geochemical cycling of selected redox-sensitive elements (U and Mo) in the estuary of the Ganga (Hooghly) River. Being dominated by monsoonal climate and characterized by large suspended sediment load, the Hooghly River estuary (HRE) provides an opportunity to study the impact of variable water discharge and suspended sediment concentration on the nature and magnitude of elemental cycling via solute-particle interaction in the estuarine mixing zone. We have investigated the chemical compositions of the (i) river/estuary water samples, (ii) coexisting suspended particulate matter (SPM), (iii) bed sediments, (iv) exchangeable phases of the sediments, (v) estuarine core sediments, and (vi) urban and industrial effluent waters. Specifically, we seek to determine if the estuary acts as a source or sink for these elements or if they behave perfectly conservatively. Investigation of the coexisting dissolved and solid phases allows us to evaluate the nature and intensity of solid-solution interaction processes in modifying the dissolved distributions of U and Mo. Using data of the dissolved, bulk SPM and its exchangeable phases in the mass balance calculations, it is evaluated whether the excesses (or deficit) of dissolved U and Mo are sustained by their complementary loss from (or gain onto) the suspended particulate matter. Furthermore, the role of tidally-induced resuspended sediments and suboxic diagenesis in the sediment column is brought out through the compositions of the bottom and core sediments. The data of industrial and urban effluents are utilized to assess the role of anthropogenic source(s) in supplying U and Mo. Finally, we evaluate the magnitude of modification of riverine dissolved fluxes of these elements due to the estuarine processes.

Probing the Hidden Universe: Direct and Indirect Searches of Dark Matter

Date

2024-03-19

Speaker

Dr. Divya Sachdeva

Venue

Online ---> https://imeet.vconsol.com/join/9022656493?be_auth=NTAzNzE4

Abstract

Recent years have seen strong support for dark matter (DM) from observations on a multitude of scales, with a range of experiments operational, approved, or proposed to explore DM theories across various masses. The vastness of the parameter space of DM necessitates exploring model-dependent and model-independent approaches while investigating the symbiosis between astrophysical observations and particle physics experiments. In this talk, I will highlight my past and present research projects where we obtained limits on parameter space of various DM candidates and outline future research plans. I will conclude with a discussion on two key areas of my research plan: a) the impact of potential interaction of DM with Standard Model (SM) in altering its velocity distribution and expanding the detectable parameter space for direct detection experiments; and b) the presence of non-relativistic DM near supermassive black holes, which can lead to high-density DM regions that produce robust annihilation signals, thereby enhancing our indirect search capabilities.

Exploring the interplay of gravity, magnetic field, and turbulence at the hub of a Giant molecular cloud G148.24+00.41

Date

2024-03-19

Speaker

Vineet Rawat

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

he relative importance of magnetic fields, turbulence, and gravity in the early phases of star formation is still not well understood. The plane of sky component of the magnetic field can be traced indirectly using the dust polarization of background starlight. In a recent work, we report the first high-resolution dust polarization observations at 850 μm around the most massive clump, located at the hub of the Giant Molecular Cloud G148.24+00.41, using SCUBA-2/POL-2 at the James Clerk Maxwell Telescope. In this talk, I will discuss the relative orientations of intensity gradients and local gravity with the magnetic field, which shows a dominant role of gravity in driving the gas collapse as the magnetic field orientations and gravity vectors seem to point towards the dense clumps. A better correlation of intensity gradients with the B-fields tells that matter is following the B-field lines or vice-versa. Our observation has resolved the massive clump into multiple substructures. We study the magnetic field properties of two regions, central clump (CC) and northeastern elongated structure (NES). Using the modified Davis–Chandrasekhar–Fermi method, we determine their magnetic field strengths to be around ∼24.0 ± 6.0 μG and 20.0 ± 5.0 μG, respectively. I will present the analysis done over CC and NES regions to understand their localized magnetic field-to-gravity ratio, magnetic criticality, Alfvénic state, and overall energy budget.

Hearing the Universe Hum with Gravitational Waves and Primordial Black Holes at Pulsar Timing Array: astrophysical, cosmological and particle physics interpretations

Date

2024-03-18

Speaker

Dr. Anish Ghoshal

Venue

Room no: 469 (Main Campus)

Abstract

We will discuss interpretation of the nHz stochastic gravitational wave background (SGWB) seen by NANOGrav and other Pulsar Timing Array (PTA) Collaborations in the context of supermassive black hole (SMBH) binaries. The frequency spectrum of this stochastic background is predicted more precisely than its amplitude. We will discuss how Dark Matter friction can suppress the spectrum around nHz frequencies, where it is measured, allowing robust and significant bounds on the Dark Matter density, which, in turn, controls indirect detection signals from galactic centers. Next we will discuss alternative cosmological interpretations including cosmic strings, phase transitions, domain walls, primordial fluctuations and axion-like physics each of which may lead to Primordial Black Hole formation. Focussing on primordial black holes (PBHs) production in various cosmological scenarios involving single-field inflation, multiple fields, particularly the Curvaton model, as well as those based on the presence of remnants dominated by the false vacuum and show the PBH formation from these remnants including the contribution from the false vacuum and the bubble walls, during strong first-order phase transition by estimating the collapse using the hoop conjecture. Such PBH formations have associated Gravitational Waves from bubble collisions, the spectral shape of which is distinct from that of scalar-induced GW. Finally we will end by putting these comparative studies to test via We will discuss how well these different hypotheses fit the NANOGrav data, both in isolation and in combination with SMBH binaries, and address the questions: which interpretations fit the data best, and which are disfavoured. Finally we also discuss experimental signatures that can help discriminate between different sources of the PTA GW signals with complementary probes using CMB experiments and searches for light particles in DUNE, IceCUBE-Gen2, neutrinoless double beta decay, and forward physics facilities at the LHC like FASER nu, etc. along with Primordial Black Hole formation and its constraints.

Volcanism along the rings of the crisium basin on the moon date

Date

2024-03-15

Speaker

Ms. Neha Panwar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Crisium Basin (17.0 °N, 59.1 °E) is a ~1100 km multi-ring basin formed at ~4.07Ga hosting widespread volcanism within its central depression and along its rings. The results from Luna 24 and remote sensing observations suggest that the basalts of the Mare Crisium have been emplaced between 3.45 to 2.52 Ga. The basalts from the Inner Depression display a range of composition as indicated by their TiO2 abundances that vary from 6-10 wt.% in the east to <2 wt.% in the west. The sub-surface units exposed by larger craters are also compositionally distinct from Mare Crisium basalts, thereby revealing the possibility that the composition of the basalts evolved with time. However, there has been no comprehensive study regarding the composition and emplacement timescales of the basalts along rings of the Crisium Basin. The basalts along the rings of the Crisium Basin have been emplaced within Mare Undarum, Mare Spumans, Mare Anguis, Cleomedes Crater and Lacus Bonitatis. My recent study identified Marginis West as an episode of volcanism along the outermost ring of the Crisium Basin. This study, for the first time, examines the compositional diversity and ages of the basalts emplaced along the rings of the Crisium Basin to better understand its geological evolution. In the seminar, the results will be discussed.

Umbral flashes and their possible association with running penumbral waves

Date

2024-03-14

Speaker

Mr. Sandeep Dubey

Venue

USO Seminar Hall

Abstract

Sunspots ; being magnetic hotspots ; play a vital role in governing dynamics of the solar atmosphere. Umbral flashes are one of the most dynamic phenomena observed in the sunspot umbral chromosphere. Flashes are observed as small scale intensity enhancements having an approximate periodicity of 3 minutes, interpreted as manifestation of shock developed due to steepening of slow mode waves. Slow mode waves with frequencies above acoustic cutoff frequency get channeled to higher layers of atmosphere along inclined magnetic field lines. Another interesting wave phenomenon observed in sunspot penumbra are running penumbral waves (RPW), appearing as concentric dark and bright rings of disturbances propagating from the umbra-penumbra boundary to edge of penumbra, with a periodicity of 5 minutes approximately. RPWs are also considered as slow mode waves propagating along inclined magnetic fields. In this division seminar; I shall discuss results obtained by analyzing spectroscopic observations of umbral flashes in Ca II 8452 Å line; recorded by narrow-band imager working with the Multi-Application Solar Telescope (MAST). I shall also discuss the aspect of association of running penumbral waves with umbral flashes.

X-ray and Optical Studies of the Be/X-ray Binary IGR J06074+2205

Date

2024-03-14

Speaker

Birendra Chhotaray

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

X-ray binaries are bright X-ray sources consisting of a compact object (white dwarf, neutron star, and black hole) and a main-sequence star as its companion. The compact object emits X-rays by accreting mass from the companion star, which is bright in optical. High-mass X-ray binaries (HMXBs) are one type in which the companion is a massive (M >10 M⊙, O or B spectral type) main-sequence star. In the Be/X-ray binary, a subtype of HMXB, a compact object (mostly neutron star) accretes mass from the circumstellar disc of its Be companion. We aim to understand the X-ray and optical properties of the Be/X-ray binary IGR J06074+2205. We have analyzed the X-ray data obtained from NuSTAR and NICER observatories to investigate the properties of the neutron star and optical data from MIRO and HCT to probe the properties of the Be companion. In this talk, I will discuss the time and luminosity-dependent properties of the Be/X-ray binary, which is obtained by timing and spectra analysis of X-ray and optical data.

Changing-State AGNs: Challenging our Understanding of AGNs

Date

2024-03-13

Speaker

Dr. Arghajit

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Changing-state active galactic nuclei (CSAGNs) show the appearance and disappearance of broad emission lines in their UV/optical spectra on timescales of months to decades. The CSAGNs can not be explained by standard unified model AGNs that successfully explain all AGN phenomena in the last four decades. Here, we will discuss our current understanding of CSAGNs. We will also discuss open questions and future prospects.

Large Submarine Groundwater Discharge from Karnataka Coast, Southwestern India: Quantification, Influencing Factors, and Ecological Implications

Date

2024-03-12

Speaker

Dr. Lino Yovan

Venue

NanoSims Hall

Abstract

Submarine groundwater discharge (SGD) contributes a notable portion, ranging from 6-12%, of the total freshwater inputs to the global ocean and has immense implications in coastal zone management. In my presentation. I will discuss our study focused on delineating the SGD dynamics along the Karnataka coast, specifically its flow into the Arabian Sea. Employing subsurface seepage meters, the first of their kind, we quantified the fluxes of carbon, nutrients, and trace metals associated with SGD. Our findings reveal that the estimated SGD rates in this locale surpass those reported elsewhere globally, with the productivity of the coastal aquifer and monsoonal precipitation identified as primary influencers of SGD discharge mechanisms. By employing subsurface seepage meters, we achieved precise estimations of seepage rates, without the influence of tides and waves that traditional seepage meters face. Additionally, we observed that SGD flow dynamics are linked to inland hydraulic gradients and tidal fluctuations, along with the extensive coastal deposits. These findings emphasize the need for proactive coastal ecosystem conservation, especially amid escalating climate change and human activities.

Understanding the innermost geometry of accreting Seyfert galaxies using X-ray reverberation techniques

Date

2024-03-11

Speaker

Dr. Mayukh Pahari

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Signs such as rapid X-ray fluctuations and significant variability in RMS values imply that the X-ray emitting source in an accreting black hole system is nearest to the black hole. However, details regarding its size, shape, and precise position remain unclear, often linked to the base of the radio jet along the black hole's vertical spin axis. X-ray reverberation, a vital observation technique involving coronal X-rays reflecting off the inner accretion disc, indicates a delayed, modified emission. Interestingly, the time delay measurements from such a modified emission in UV and optical follow standard thin disc theory; however, X-ray departs. In this talk, I will discuss how X-ray reverberation observationally differs from other wavelengths and how the lamppost geometric configurations can be used to explain the measured X-ray reverberations in Seyfert galaxies.

Hub-filament systems as progenitors of star cluster formation

Date

2024-02-29

Speaker

Dr. M. S. Nanda Kumar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

All stellar clusters form in hub-filament systems (HFS) and massive stars form in the hubs. The HFS structure is essentially that of what is generally referred to as molecular clouds (few to few tens of parsec) and hubs represent the central gravitating clump (1 pc) within HFS. I will first review our present knowledge of HFS and discuss how it can explain known properties of stellar clusters. Next, I will present our ongoing work to explore the star-gas relationship in the MonR2 HFS to understand whether molecular clouds are long lived resulting in slow star formation or vice versa. I will conclude by discussing the latest notions of how galaxies convert the interstellar medium (ISM) into stars and maintain the ISM life-cycle.

Deglacial evolution in ventilation of the western equatorial Atlantic Ocean and its link to atmospheric CO2 changes

Date

2024-02-27

Speaker

Dr. Partha Jena

Venue

NanoSims Hall

Abstract

The marine and atmospheric carbon pools are strongly linked to one another and the air-sea gas exchange processes considerably control the atmospheric CO2 budget. In this regard, Radiocarbon provides unique insights into the air-sea exchange and the Ocean’s ability to sequester atmospheric CO2. We combine results from Radiocarbon measurements of foraminifera specimens and intermediate complexity numerical model simulations to understand the role of the Atlantic Ocean and Atlantic Meridional Overturning Circulation (AMOC) in driving atmospheric CO2 changes. We reconstruct a ‘Radiocarbon ventilation age’ record from the intermediate depth western equatorial Atlantic (WEA) Ocean, which acts as a gateway for CO2 trapped in North Atlantic Deep Water (NADW) before getting released to the atmosphere in the Southern Ocean. The model simulation highlights a near-complete shutdown of AMOC during Heinrich Stadial (HS)-1, resulting in a poorly ventilated Atlantic Ocean that aligns well with the high B-P ventilation ages at our study site. On the contrary, the Atlantic Ocean was properly ventilated during North Atlantic interstadials i.e., the Holocene and the Bølling–Allerød (BA) resulting in low B-P ventilation ages. The high resolution (resolved at every 150 years) Radiocarbon ventilation age record focuses on the deglaciation period (~18 to 12 ka BP) during which multiple short-term (~200 years) CO2 overshoot events have been observed amid a steady CO2 rise. Concurrent with the CO2 overshoot events, we observe prominent ventilation age drops in WEA intermediate depths. A strong coupling between AMOC strength, atmospheric CO2 and North Atlantic temperature is observed during the 14.8 ka and the 11.7 ka events. On the contrary, in the case of the 16.3 ka event, the rise in atmospheric CO2 was not directly associated with AMOC strength. Nevertheless, it is plausible that the Southern Ocean remained a significant source of atmospheric CO2 during that period. In this presentation, our findings underlining the important role played by the Atlantic Ocean and AMOC in deglacial carbon cycle changes will be discussed.

Heliospheric Propagation of Coronal Mass Ejections

Date

2024-02-27

Speaker

Sandeep Kumar

Venue

Online:https://meet.google.com/uue-rpmm-upb

Abstract

Coronal Mass Ejections (CMEs) represent explosive releases of solar plasma and magnetic fields into the heliosphere, exerting significant influence on interplanetary space weather. The dynamics of CMEs involve the eruption of vast amounts of solar material and magnetic energy, driven by complex processes within the solar corona. As these charged particles are ejected into the heliosphere, they interact with the ambient medium. Upon arriving at the Earth they create disturbances that can affect the Earth's magnetosphere, ionosphere, and geomagnetic field. Understanding the initiation and propagation of CMEs is crucial for predicting their potential impact on space-based technologies, communication systems, and power grids. In this talk, I will discuss various factors affecting heliospheric propagations of coronal mass ejections and consequently how this interaction of the CMEs with the ambient medium can affect its impact on the Earth.

The Gorkov-Teitelbaum thermal activation model for the cuprates

Date

2024-02-27

Speaker

Prof. Navinder Singh

Venue

Room no: 469 (Main Campus)

Abstract

A brief overview of this very successful phenomenological model for the pseudogapped state of cuprates will be presented. A recent work on the pseudogapped state on a related system (Strontium Iridate) using this model will be discussed.

Reprocessing of pvo radio occultation data from 1978-1982 date

Date

2024-02-23

Speaker

Prof Martin Pätzold, Director, Riu-Planetary Research At Cologne

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

RIU-Planetary Research has secured funding support for the reprocessing and interpretation of the Pioneer Venus Orbiter (PVO) radio science experiment ORO original raw open-loop occultation data recorded between 1979 and 1982. A limited selection of original ORO profiles, primarily comprising electron density profiles, with only a few temperature profiles, was obtained from an NSSDC server and published by Withers(2020) on a Boston University server. To achieve our goals, we are utilizing state-of-the-art software code along with an updated version of the Venus gravity field and newly processed PVO orbit data provided as SPICE kernels. I shall present atmospheric and ionospheric profiles derived from S-band and differential Doppler recordings, respectively, processed from the original Pioneer Venus Orbiter raw open-loop data sets. We will then compare these profiles with VEX-VeRa radio occultation profiles obtained under comparable observation conditions, as well as with the few existing original PVO profiles retrieved from the Boston University server account (Withers, 2020).

Forces and dynamics involved in evolution of IDP in solar system date

Date

2024-02-16

Speaker

Ms. Aanchal Sahu

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Dust is the major constituent of Solar System objects which is present everywhere in the Interplanetary Space. These dust particles are originated by diverse sources such as Asteroid Belt, Kuiper Belt, Oort Cloud, and residual debris left since the formation of the Solar System. Occasionally, comets traversing from outside of Solar System are expected to bring volatiles and leave dust particles due to sublimation. Larger particles tend to migrate inward, while smaller ones are swept outward. When hypervelocity dust encounters Earth's atmosphere, it ablates, forming a metallic ion layer. On the Moon, these particles impact the surface directly, ejecting material that may escape lunar gravity. These dust particles play a vital role in various observed phenomenon such as Zodiacal Light and Meteor Showers. During their inward motion towards the Sun, they encounter a complex interplay of gravitational and non-gravitational forces like Poynting-Robertson Drag, Radiation Force, Solar Wind Force, and Lorentz Force depending upon the size and position of the particles in Inner Solar System. These forces dictate the dynamics of the particles, leading to changes in their orbital elements. The capture and trapping of dust particles near a planet can be understood by the solution of N-body integration formulation. In my discussion, I will present the flux of Asteroidal and Cometary Dust within the Inner Solar System. Additionally, I will delve into the forces and how they shape orbital elements, leading to evolution of IDP. Further, I'll share its connection to my ongoing research work.

Timekeepers in Earth Sciences: Application of U-Pb geochronology to earth and planetary processes

Date

2024-02-13

Speaker

Dr. Amal Dev J

Venue

NanoSims Hall

Abstract

The application of insitu analytical techniques has garnered substantial attention in the past decades owing to its increasing potential in resolving many fundamental problems in earth and planetary processes. Recent advancements in the application of texturally controlled laser ablation (LA) ICPMS analysis of accessory mineral phases in rocks have added significantly to the petrochronological studies owing to their high spatial resolution, fast data acquisition, improved precision-accuracy, and cost-effectiveness. The insitu LA-ICPMS studies have been highly explored to unravel the geodynamic evolution of sedimentary basins; timing, nature, and duration of crust forming and crust recycling events; tectonothermal evolution of polydeformed terranes and isotopic characteristics of planetesimal bodies etc. This is in conjunction with the fact that individual accessory phases in the samples can fingerprint discrete events due to their variable response to physio-chemical conditions. Among the different isotopic systematics, the application of insitu U-Pb geochronology combined with relevant isotopic information has been widely recognized as the most robust tool to gain insights into these processes. Some relevant applications of U-Pb geochronometry along with specific case studies will be addressed in the talk with future prospects.

Soft gluon non-factorizable charm loops in B to K(*) l+l- and implications for new physics

Date

2024-02-13

Speaker

Prof. Namit Mahajan

Venue

Room no: 469 (Main Campus)

Abstract

I'll discuss some recent progress on computing the non-factorizable soft gluon contribution to B to K(*) l+l- decays arising from charm loops. These constitute a considerable hadronic uncertainty when comparing with the experimental data. Some implications for new physics in these modes will be discussed.

Understanding the Impact of Coronal Mass Ejections on Space Weather: Integrating Observations and Modelling

Date

2024-02-12

Speaker

Dr. Ranadeep Sarkar

Venue

USO Seminar Hall

Abstract

Coronal mass ejections (CMEs), the most violent eruptive phenomena occurring in the heliosphere, are recognized as one of the major sources for space weather disturbances. CMEs erupt in the form of gigantic clouds of magnetized plasma from the Sun and can reach Earth within several hours to days. If the magnetic field inside an Earth-directed CME or its associated sheath region has a southward-directed north-south magnetic field component (Bz), then it interacts effectively with the Earth’s magnetosphere, leading to severe geomagnetic storms. Therefore, it is crucial to predict the strength and direction of Bz inside Earth-impacting interplanetary CMEs (ICMEs) in order to forecast their geo-effectiveness. Since the magnetic field of solar eruptions cannot reliably be measured via remote means, and direct continuous measurements of the Earth impacting solar transients are routinely available only very close to our planet, modelling of CME magnetic properties is paramount. In this talk, I will present a space weather modelling framework using both analytical and global MHD approaches that could prove to be an operation space weather forecasting tool to predict the geo-effectiveness of CMEs. This talk will also showcase the utilisation of multi-wavelength remote-sensing observations as well as multi-spacecraft in-situ observations at different heliocentric distances to constrain the space weather forecasting models. Further, I will discuss how data obtained from India's space-based solar observatory, Aditya L1 will play a crucial role to enhance our understanding on the CME initiation mechanism.

Extreme Indian Monsoon states lead to oceanic productivity collapses

Date

2024-02-07

Speaker

Dr. Kaustubh Thirumalai

Abstract

Indian summer monsoon (ISM) hydrology fuels biogeochemical cycling across South Asia and the Indian Ocean, exerting a first-order control on food security in Earth's most densely-populated areas. Despite projected ISM intensification under greenhouse forcing, large uncertainty surrounds future Indian Ocean stratification and primary production -- processes key to the health of already vulnerable fisheries in the region. Here, we present centennially-resolved records of ISM runoff and marine biogeochemical fluctuations in the Bay of Bengal (BoB) since the Last Glacial Maximum (LGM; ~21 ka). We find that ISM runoff was at its weakest during Heinrich Stadial 1 (HS1; 17.5-15.5 ka) and that peak freshwater discharge occurred during the early Holocene (EH; 10-9 ka). Counterintuitively, our records indicate that BoB productivity collapsed during both extreme states of peak monsoon intensity (EH) and failure (HS1). Using individual foraminiferal analyses (IFA) we demonstrate that both extremes were associated with upper-ocean stratification; whereas thermally-mediated stratification suppressed mixing and nutrient-delivery during HS1, outflow-induced stratification driven by strengthened ISM runoff curtailed productivity during the EH. In contrast to the latest Earth-system model projections, our paleoceanographic results raise the possibility of future deterioration in BoB productivity under strengthening monsoon seasonality.

Linking lepton number violation with supersymmetry breaking

Date

2024-02-07

Speaker

Dr. Ketan M. Patel

Venue

Room no: 469 (Main campus)

Abstract

Supersymmetry and lepton number violation are apparently distinct hypothetical phenomena introduced to address two very fundamental issues of the Standard Model of particle physics: the gauge hierarchy problem and neutrino masses, respectively. In this talk, I will highlight how these phenomena can be linked. Consequences for direct searches, in terms of displaced vertex signatures, shall also be outlined.

Multi-line Spectropolarimetry: Our Key to Understand the Solar Atmosphere

Date

2024-02-06

Speaker

Dr. Rahul Yadav

Venue

USO Seminar Hall

Abstract

Multi-wavelength observations from various telescopes reveal frequent heating and eruptive events in the solar atmosphere, such as Ellerman bombs, UV bursts, jets, surges, and flares. These events not only heat the lower atmosphere (the chromosphere and transition region) but also impact the dynamics of the corona. Despite decades of study, predicting these events and understanding their detailed mechanisms throughout the solar atmosphere remains unclear. Multi-line spectropolarimetric observations spanning different layers of the solar atmosphere are crucial for understanding various aspects of heating events. In this talk, I will discuss how such observations can be used to construct an observationally driven model of heating events using state-of-the-art multi-line inversion methods. Additionally, I will present recent results from the analysis of multi-line spectropolarimetric observations of a C4-class flare observed with the Daniel K. Inouye Solar Telescope. Finally, I will explore the potential for investigating heating events through coordinated observations from the MAST, IRIS, and Aditya-L1 telescopes.

Insights into the abrupt climatic events (ACE) of Holocene: A paleoclimate conundrum

Date

2024-01-30

Speaker

Dr. Upasana Swaroop Banerjee

Venue

NanoSims Hall

Abstract

The Indian Summer Monsoon (ISM) plays a pivotal role in the socio-economics of the Indian subcontinent and global climate system. The recent anomalous behaviour of ISM invigorates the need to address spatio-temporal changes of ISM during the ongoing interglacial period, the Holocene Epoch (~11.8 ka- Present). The Holocene has been characterised by various Abrupt Climatic Events (ACE) such as 8.2 ka, 4.2 ka, Bond events, Little Ice Age, etc., based on colossal studies from high latitude regions. Most of these ACEs have been recognised in global natural proxies, however, ISM being a major part of the global climate system, remains poorly understood in terms of its response towards the ACE of the Holocene. Further, the association of the Indian monsoon system with natural forcing and climate variables have remained elusive. In the present talk, a synoptic assessment of Indian monsoon variability and its response towards globally established ACEs will be discussed.

CARMENES: exoearths from Spain

Date

2024-01-25

Speaker

Dr. José A. Caballero

Venue

Online: https://meet.google.com/fwp-cnit-rko

Abstract

Calar Alto high-resolution search for M dwarfs with Exoearths with Near-infrared and optical Échelle Spectrographs (CARMENES). In other words, it is a "machine for discovering planets like our Earth around the closest stars to our Sun". CARMENES took six years from a concept to the start of operations, and a couple more years of initial data collection until the first science publication, but now is revolutionising our knowledge on exoplanets and their stars in our immediate vicinity. In my talk I will describe what CARMENES is: (i) an ultra-stabilised two-channel spectrograph at an almost dedicated 3.5 m telescope in southern Spain that covers in high spectral resolution and without big gaps from 0.52 μm to 1.71 μm; (ii) a science project aimed at comprehensively searching for and studying planetary systems with nearby, bright, M-dwarf hosts, but that also investigates transiting planets around other stars; and (iii) the German-Spanish consortium that designed and built the instrument and that has operated it under guaranteed and legacy time observations.

Detecting tidal deformation and decay

Date

2024-01-18

Speaker

Dr. Susana Barros

Venue

online : https://meet.google.com/myq-ynxh-zrk

Abstract

Tidal forces between short-period planets and their host stars are extreme. These lead to the deformation of the planet and the shrinkage of the planet’s orbit. Using the new ESA mission CHEOPS we are attempting to measure both these effects for a sample of exoplanets. Measuring the tidal deformation of the planet would allow us to estimate the second degree fluid Love number and gain insight into the planet's internal structure. Measuring the tidal decay timescale would allow us to estimate the stellar tidal quality factor, which is key to constraining stellar physics. WASP-103 was our first target since it had the largest estimated signature of the tidal deformation. I will present the first detection of the tidal deformation of a planet directly from its light curve. This allowed us to measure the Love number of WASP-103b. I will also present our measurements of the tidal decay of a few targets including WASP-103b and explore our future perspectives.

Cosmic Ray Transport in Magnetohydrodynamic Turbulence

Date

2024-01-17

Speaker

Dr. Kiritkumar Makwana

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Cosmic rays are affected by magnetic fields as they travel across the universe. Because of the turbulent and chaotic magnetic field lines in the intergalactic and interstellar medium and the heliosphere, cosmic rays are deflected and can exhibit random motion. It is essential, then, to understand how these cosmic rays diffuse out of a particular region of interest, carrying energy, mass, and momentum along with them. This diffusion process depends on the structure of the magnetic field lines in magnetohydrodynamic (MHD) turbulence. I will describe numerical simulations of this diffusion process using test particles in MHD turbulence simulation data. We investigate diffusion at both small and large scales (compared to the gyro-radius). At large scales we get normal diffusion whereas at small scales we observe Richardson diffusion, which is a type of super-diffusion. Different MHD wave modes are decomposed and diffusion due to them individually is also studied. The scaling of the diffusion coefficients with Alfven Mach number is calculated and roughly matches theoretical expectations. It is shown that the fast magnetosonic modes dominate in the cosmic ray diffusion process.

Rheology of the lower crust and its implications for geodynamic studies

Date

2024-01-16

Speaker

Dr. Sagar Masuti

Venue

NanoSims Hall

Abstract

Postseismic relaxation from large earthquakes and postglacial rebound from the melting of ice sheets induce transient deformation of the solid Earth, particularly in the deep crust and upper mantle. The melting of large ice sheets due to climate change further results in sea-level rise, which is of great societal concern. The deformation of the lower crust is mainly controlled by feldspar. The mechanical properties of feldspar at steady-state are well constrained. However, the physical mechanism underlying transient creep, an evolutionary, hardening phase converging to a steady state asymptotically, is still poorly understood. In order to constrain flow law parameters for the transient creep of feldspar, we performed constant strain rate deformation experiments on synthetic fine-grained anorthite (Ca end member of feldspar) aggregates under wet conditions using a Paterson-type gas deformation apparatus. We analysed the starting and deformed samples in optical microscopy, scanning electron microscopy (SEM), and transmission electron microscopy (TEM). We constrain the mechanical data using a Burgers assembly with a thermally activated nonlinear stress versus strain-rate relationship for the dashpots. I will discuss the inferred flow law parameters of the transient creep and demonstrate their importance by using these parameters to study the postseismic deformation following the 2016 Mw 7.0 Kumamoto earthquake.

Exploring the Dark Sector: New Regimes, New Ideas

Date

2024-01-15

Speaker

Dr. Anirban Das

Venue

Online---> https://bluejeans.com/613207389/4345

Abstract

The overwhelming evidence from astrophysical and cosmological observations have established the existence of dark matter in our Universe. Even though we know that it forms most of the matter, we do not know anything about its nature. Decades of experiments have not yielded any conclusive detection yet. So it is high time to look beyond the simplest models, and broaden the search for nonstandard theories of particle dark matter and cosmology. In the first part of my talk, I will describe a couple of new proposals to use novel materials to look for light sub-GeV dark matter. In the second part, I will briefly describe the nonstandard cosmology of self-interacting neutrinos, how the latest data from Planck and ACT affect the model, and the current status of its link to the Hubble tension.

Lunar south polar landing site characterization from de Gerlache to Shackleton ridge region

Date

2024-01-12

Speaker

Ms. Sachana A S

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Moon has gained significant scientific and exploration values after the detection of volatile species of diverse nature by recent lunar missions. The lunar poles with presence of permanently shaded regions (PSRs) serve as a natural laboratory for understanding processes work on cold traps of lunar poles. Near future lunar explorations majorly focused on detailed mapping and quantification of water ice exposures using rovers, on surface and subsurface levels. Here, I present a case study of four potential landing sites on the ridge connecting de-Gerlache and Shackleton craters, all situated within the expansive South-Pole Aitken (SPA) basin, by integrating information from recent lunar missions. The South Pole emerges as a unique and compelling area for exploration, promising insights into the compositional and structural diversity and chronological aspects of the basin also hosting several potential PSR’s. I will discuss detailed characterisation of these sites based on terrain characteristics, which include slope, illumination, surface roughness, surface temperature, geomorphology, accessibility to nearby PSRs, compositional diversity, and trafficability.

Probing the habitability conditions for the Earth-like exoplanets by their atmosphere characterization

Date

2024-01-11

Speaker

Manika Singla

Venue

Online Mode: https://meet.google.com/meg-tqis-hzu

Abstract

In this talk, I will discuss about the ways to probe the habitability conditions on Earth-like exoplanets which lie in their host-star’s habitable zone as these exoplanets are the potential candidates for the habitability. We modelled the atmospheres of the Earth-like exoplanets by computing their reflection spectra, transmission spectra and the polarization phase curves. We also computed this for nine known Earth-like exoplanets (including Proxima Centauri b and Trappist-1e), which orbit around stars of spectral types G, K and M and estimated their maximum values of Bond Albedo. For this purpose, we assumed certain initial conditions on the atmospheric Temperature-Pressure profiles and the atmospheric chemical compositions and used the opacity data to solve the radiative transfer equations. I will further discuss about this in detail during the talk. Finally, I will discuss the profound effects of various surface compositions of the planet, clouds, orbital inclination angle, presence of biomolecules like H2O, CH4, O3, etc. on the reflection, transmission and the polarization of the planet. I will conclude the talk by discussing how our work will greatly enrich the upcoming search for the habitable exoplanets using big telescopes like HabEx, ARIEL, HWO, TMT, etc.

Making and collapse of mountain belts: Insights from petrography, thermodynamic modelling and diffusion kinetics

Date

2024-01-09

Speaker

Dr. Nilanjana Sorcar

Venue

NanoSims Hall

Abstract

Metamorphism, partial melting in conjunction with uplift of the deep crustal rocks are integral part of mountain building process or orogenesis. Recognizing such crustal processes has an important bearing on geodynamics as it provides the information on the tectono-thermal history of the crust. Petrography, thermodynamic modelling and diffusion kinetics are key approaches in decoding metamorphic, cooling and exhumation (upliftment) history of a mountain / orogenic belt by simulating different temperature and pressure conditions of metamorphism over time as well as cooling/exhumation rate of the deep crustal rocks. New analytical capabilities, in particular, the development of the electron micro-probe, played an enabling role by providing the means of analyzing small volumes of materials in different textural settings in intact rock samples which is crucial to develop thermodynamic and diffusion modelling in such study. In this talk, I will address the nature of tectonometamorphic evolution of young and active as well as ancient mountain belt from India and East Antarctica to show how crustal rocks evolve through geological time in different P-T regime. The development of improved methods of diffusion kinetics using compositional zoning of mineral (e.g. garnet) in combination with petrologically constrained paths of thermal evolution will be highlighted to gain insights into the nature of cooling of high- grade metamorphic rocks, as well as into the tectonic evolution of an orogenic belt (e.g. Himalayas, Eastern Ghats Belt etc.). Finally, I will talk about my future research direction using the integrated studies of mineralogy, thermodynamic modelling and diffusion kinetics to the field of Planetary Sciences, for example, to the domain of shock metamorphism and mineralogical studies of other planetary rocks.

Space weather effects on venusian ionosphere

Date

2024-01-05

Speaker

Mr. Satyandra M. Sharma

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Venusian ionosphere is influenced by solar activity and solar cycle variations, changing its characteristics, including V2 and V1 morphology, photoelectron production rates, and electron density. Solar events such as flares and solar energetic particles (SEPs) induce significant enhancements in electron density, altering the ionosphere's chemical composition. The radio occultation experiment provides an important tool to study the ionospheric characteristics. I will present the current understanding of the Venusian ionosphere under different space weather conditions and give a brief detail on the methodology that I will use to study the responses, to both average and extreme space weather components.

Probing the magnetic field and gas kinematics in the IRDC G11.11-0.12, Galactic "Snake"

Date

2024-01-04

Speaker

Omkar Jadhav

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Numerous observational investigations have demonstrated that Infrared Dark Clouds (IRDCs) are important sites for studying the birth of embedded protostars including massive stars. IRDCs appear as absorption features against the galactic background in mid-infrared images. Magnetic fields are thought to play a crucial role in the mass accretion and stability of IRDCs. However, the exact role of magnetic fields in the early stages of star formation remains unclear. My present work focuses on the Galactic ‘Snake’ IRDC G11.11-0.12, which is known to host early phases of star formation activities. We have studied the plane of the sky magnetic field derived using the emission polarization and gas kinematics toward the entire IRDC. The existing JWST near-infrared images reveal signatures of star formation, which are new findings and has not been reported in existing literature. In this talk, I will present several new results about the Galactic "Snake" in more detail.

Observations and modelling of coronal mass ejections to understand their space weather effect

Date

2024-01-04

Speaker

Dr. Ranadeep Sarkar

Venue

USO Seminar Hall

Abstract

Coronal mass ejections (CMEs) are one of the major sources for space weather disturbances. If the magnetic field inside an Earth-directed CME or its associated sheath region has a southward-directed north-south magnetic field component (Bz), then it interacts effectively with the Earth’s magnetosphere, leading to severe geomagnetic storms. Therefore, it is crucial to predict the strength and direction of Bz inside Earth-impacting interplanetary CMEs (ICMEs) in order to forecast their geo-effectiveness. Since the magnetic field of solar eruptions cannot reliably be measured via remote means, and direct continuous measurements of the Earth impacting solar transients are routinely available only very close to our planet, modelling of magnetic properties is paramount. In addition to forecasting the strength of Bz, another significant challenge in space weather prediction involves accurately estimating the arrival time of ICMEs. An in-depth understanding of the initiation mechanism of CMEs is crucial for enhancing our ability to provide extended lead times in predicting when ICMEs will reach Earth. In this talk, I will highlight how data obtained from India's space-based solar observatory, Aditya L1 will play a crucial role to enhance our understanding on the CME initiation mechanism. This talk will also showcase the utilisation of Aditya-L1 data in conjunction with the resources of existing space-based observatories as assets for space weather forecasting. In particular, a space weather forecasting framework will be presented using both analytical and global MHD approaches. Further, I will discuss a recently developed flux-rope model implementation to the global MHD models that could prove to be a major step-forward in forecasting the geo-effectiveness of CMEs.

Isotopic composition of atmospheric water vapour: recent observations and future potentials

Date

2024-01-02

Speaker

Prof. M. G. Yadava

Venue

NanoSims Hall

Abstract

Water vapour is a good tracer of atmospheric circulation. The isotopic composition of atmospheric moisture (δ18O and δD) can provide unique constraints on how water is transported, mixed, and changes phase and is thus a valuable tool in the study of the Earth’s hydrologic cycle and for improved understanding of paleoclimate proxies. We have recently started looking into the dynamics of ambient water vapour using stable isotopes as a primary tool. With the adaptation of the laser spectroscopy method for measuring ambient air-water isotopic composition, studies on atmospheric vapour at a temporal resolution of ~100 seconds are possible and are becoming significant topics in understanding hydrological perturbations on daily to seasonal scales. Current measurements, complexities in the method, and future applicability will be discussed.

Stability and mobility of lunar water-ice: current understanding through thermophysical modelling

Date

2023-12-29

Speaker

Ms. Ambily G

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Lunar poles have been confirmed as the regions where water-ice can be stable for long periods of time. The temperatures and thermophysical environment of these areas make them favorable to cold-trap volatiles and are potential sites for future lunar missions. The surface ice will be transported to subsurface through various mechanisms, depending on the temperature and regolith characteristics. Knowledge about these processes will help us targeting more accessible and resourceful sites in future. In this talk, I will discuss the present understanding of stability and transport of water-ice through thermophysical modelling studies, and explore how the illumination conditions change the surface temperatures on the Moon.

Survey of Bare Active Galactic Nuclei in the Local Universe (z < 0.2): On the Origin of Soft Excess

Date

2023-12-28

Speaker

Prantik Nandi

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Active Galactic Nuclei (AGNs), a subclass of Super-Massive Black Holes (SMBHs) emit radiation across the electromagnetic spectrum. The extreme luminosity of the AGNs arises from the accretion of matter onto the Super Massive Black Holes (SMBHs), forming an accretion disk that generates thermal photons. In the X-ray range, the inverse Compton scattering of these photons by the electron cloud, the Compton cloud, produces a power-law spectrum. Therefore, X-ray observations provide detailed insights into the inner accretion disk and Compton cloud in details. The soft excess, an excess emission below 2 keV, is an extraordinary feature in the X-ray spectra for most Seyfert 1 AGNs. The origin of soft excess is one of the major open questions in AGN research. Initially thought to be blackbody radiation, the high disk temperature corresponding to soft excess emission contradicts standard theories. some cases suggest that the reflection or Comptonization could be the origin of soft excess, But these theories are unable to explain all cases. These discoveries provoked the alternate origins of the soft excess. A recent study by Nandi et al. (2023) explores the origin of the soft excess for a sample of 21 Seyfert 1 AGNs with ‘bare’ nuclei. Long-term X-ray (0.5-10.0 keV) observations from observatories like XMM-Newton and Swift/XRT reveal a strong correlation between the luminosities of the primary continuum (3.0-10.0 keV) and soft excess (0.5-2.0 keV) across the sample. From this study, we conclude that the observed correlation between the soft excess and primary continuum luminosities could have originated due to inverse Compton scattering in the Compton cloud, and both the luminosities depend on the accretion rate only.

Protoplanetary Disks: Disk Dynamics and the Distribution Of Volatiles

Date

2023-12-22

Speaker

Mr. Soumik Kar

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

A protoplanetary disk is a rotating circumstellar disk composed of dense gas and dust around a recently formed young star. Understanding its evolution is essential to understanding planet formation and the origins of our solar system. Volatiles, encompassing a diverse array of compounds such as water, carbon dioxide, and complex organic molecules, significantly impact the composition and characteristics of growing planetary bodies. Here, we will discuss the basic properties of disks, such as mass, radius, surface density, etc, from both observations and numerical models. It will help us understand the complex dynamics that shape the overall structure of protoplanetary disks and influence the spatial distribution of volatiles. Additionally, we investigate the radial temperature profiles of these disks, probing the thermal conditions that drive volatile transport and chemical reactions. We plan to develop a model in which the physical and chemical processes governing volatile distribution in protoplanetary disks are crucial model components. This study plans to provide a foundation for understanding the diverse range of volatile-rich environments in the protoplanetary disks.

Study of short GRBs and their afterglows

Date

2023-12-21

Speaker

Ashish Kumar Mandal

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Gamma-ray bursts (GRBs) are brief intense flashes of gamma-rays produced at cosmological distances. They are classified as short or long based on the bimodality of the observed duration distribution of their prompt gamma-ray emission. This empirical classification was based on hypotheses that two classes have different progenitors. Long GRBs (LGRBs) have been firmly connected to the collapse of massive stars through the detection of associated Type Ibc core-collapse supernovae. But support for the connection between short GRBs (SGRBs) and merger of binary neutron stars (BNSs) or NS-BH binaries came from indirect observational evidence, population synthesis studies, and numerical simulations. The joint detection of gravitational wave GW170817 and a SGRB (GRB170817A) on 17th August 2017 from a BNS merger confirms that BNSs are progenitors of (at least some) SGRBs. This SGRB was 2 orders of magnitude nearer and 2 to 6 orders of magnitude less energetic than SGRBs with known distances. If it were at least 30% fainter, then most of our curent GRB detectors might have missed this event. In this seminar I will discuss on the properties of prompt gamma-ray emission, early afterglow in soft X-ray, UV, optical and late afterglow in IR, radio of SGRBs, some findings which support GRB classification criterion, and highlight sensitivity of few GRB detectors.

Multi-band Polarimetric Study towards the Cluster NGC 7380

Date

2023-12-19

Speaker

Dr. Sadhana Singh

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The polarimetric study is an effective tool for providing information about the magnetic field orientation and will also reveal information about the properties of interstellar dust grains and their alignment. The polarization of background starlight through the interstellar medium is a result of the dichroic extinction of starlight through the aligned grains. In the seminar, I will present the multi-band polarimetric study of the open star cluster NGC 7380. Polarimetric observations are carried out in four filters using an ARIES imaging polarimeter from a 104-cm telescope of ARIES. The orientation of dust grains in the line of sight is found to be parallel with the Galactic magnetic field. Towards the east and southeast regions, the dust structure appears much denser than in other regions and is also reflected in the polarization distribution. Three groups of stars are identified in the Stokes plane, which suggests the presence of an additional weak magnetic field component. Additional results from the polarimetric analysis will be presented e.g. size distribution, polarizing efficiency, and foreground dust distribution. I will show the overall distribution of polarization and position angle towards Galactic anti-center direction and lastly, I will discuss future plans.

Study Of Whisler Waves And Other Plasma Waves In Venusian Ionosphere

Date

2023-12-15

Speaker

Ms. Aarti Yadav

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The ionosphere of Venus is the uppermost layer of the atmosphere where significant numbers of free thermal electrons and ions are present. The base of Venusian ionosphere is situated around an altitude of 120 km and the layer can go up to 300 km or more than that which is remarkably affected by solar activity. I shall discuss the profound influence of solar activity on the ionospheric regions. The discussion extends to Venus' induced magnetosphere, exploring the mechanisms governing its generation and shedding light on the properties of plasma within this unique planetary environment. One focus point will be the Whistler waves around Venus, their characteristics and the significance in the Venusian ionosphere. Recent findings regarding whistler waves near Venus also will be presented and I shall outline my future research direction with whistler waves around Venus

Multi-instrument studies of solar flares and energetic particles

Date

2023-12-14

Speaker

Dr. Frederic Schuller and Mr. Malte Victor Philipp Broese

Venue

USO Seminar Hall

Abstract

SPECULOOS: Hunting exoplanets of ultracool dwarfs with 1-meter ground-based telescopes network

Date

2023-12-14

Speaker

Dr. Sebastián Zúñiga-Fernández

Venue

Online Mode : https://meet.google.com/vnm-saoz-izz

Abstract

The SPECULOOS (Search for habitable Planets EClipsing ULtra-cOOl Stars) project aims to perform a transit search on the nearest (< 40 pc) ultracool (<3000K) dwarf stars. The project is based on a network of 1m robotic telescopes, composed by the four ones of the SPECULOOS-Southern Observatory (SSO) in Cerro Paranal, Chile, one telescope of the SPECULOOS-Northern Observatory (SNO) in Tenerife, and the SAINTEx telescope in San Pedro Martir, Mexico. The prototype survey of the SPECULOOS project on the 60 cm TRAPPIST telescope (Chile) discovered the TRAPPIST-1 system, composed of seven temperate Earth-sized planets orbiting a nearby (12 pc) Jupiter-sized star. The project's main motivation is to discover potentially habitable planets well-suited for detailed atmospheric characterisation with upcoming giant telescopes, like the James Webb Space Telescope (JWST) and European Large Telescope (ELT). The SPECULOOS target list contains a homogeneous selected sample of close-by low-mass and ultracool stars.The targets have been selected as low-mass dwarfs starting from the Gaia DR2 catalogue, which has been cross-matched with the 2MASS point-source catalogue. Beside conducting observations of targets from the SPECULOOS input catalog, a fraction of the available observing time of the SPECULOOS network is used to carry out different science goals, the so-called annex programmes. A large annex programme is the support of space based transit search surveys such as K2 and TESS through the follow-up of transit candidates of late-type dwarfs.The upcoming Gaia DR3 release will largely improve the parallaxes and colours for the 40 pc sample, thus encompassing more targets that were excluded in our original target list. In these talks we are going to present our observation strategy, management of our archive and scientific products. We will discuss the first results of the survey and the synergy of our programs with the Transiting Exoplanet Survey Satellite (TESS) and JWST.

Isotopic Constraints On The Accretion And Early Evolution Of Earth Date

Date

2023-12-14

Speaker

Dr Nikitha Susan Saji, Central State University, Wilberforce,Ohio, USA

Venue

Online

Abstract

There exists abundant evidence today, from meteorites and their components, for the presence of planetary-scale isotope anomalies of nucleosynthetic origin in the solar system. The observed isotopic variations testify to the differential incorporation of presolar dust grains synthesized in multiple stellar environments by accreting planets and planetesimals, although the exact mechanism behind their peculiar distribution in the solar protoplanetary disk is highly debated. Nevertheless, they carry important information about protoplanetary disk structure and dynamics, as well as the history of formation of terrestrial planets such as Earth and Mars. In this talk, I will review the extent and possible causes of nucleosynthetic isotope heterogeneity evident in solar system materials, with an emphasis on multi-element isotope variability trends in relation to neodymium. The goal is to disentangle the relative role of disk processing and heterogeneous infall in delineating the multitude of nucleosynthetic variability trends observed in solar system materials. I will also discuss how an accurate determination of the nucleosynthetic makeup of material precursors of terrestrial planets remain important towards the robust application of short-lived radioactive decay chronometers to study early planetary differentiation and subsequent geochemical evolution.

A Tale of Two Spicules

Date

2023-12-13

Speaker

Mr. Ravi Chaurasiya

Venue

USO Seminar Hall

Abstract

Spicules are the thin, elongated, hair-like features seen through a high-resolution telescope in chromospheric spectral lines such as H-alpha and Ca II lines. These spicules move upward and downward in the solar atmosphere with velocities ranging between 20 and 150 km/sec. They are believed to carry a mass flux several times greater than that of the solar wind. In this seminar, I will briefly discuss the history and initial development of the spicules and how type II spicules were discovered along the flows associated with these type II spicules in the solar atmosphere.

Astronomy in Africa for Achieving the Sustainable Development Goals

Date

2023-12-13

Speaker

Dr. Mirjana Pović

Venue

Online Mode : Google Meet Link : https://meet.google.com/nec-gqmd-tuq

Abstract

Education and its contribution to science, technology and innovation are the key points to combat poverty in the long term. Education is also a key point to empower girls and women, which is fundamental to achieve the United Nations Sustainable Development Goals (SDGs). Astronomy is a powerful tool to promote education and science but, in addition, it is also one of the leading sciences to bring strong technological developments and innovation. Africa has an amazing potential due to its natural and human resources for scientific research in astronomy. The situation of astronomy and space science in Africa has changed significantly in recent years, becoming emerging fields across the continent, and never before has it been as possible to use astronomy for development as it is today. This talk will first summarize the current status of astronomy developments in Africa. Secondly, using as an example different activities carried out for the development of education, science and technology in Ethiopia, East Africa and across the continent, it will show how through these we can fight poverty in the long term and increase in the future our chances of achieving the UN Sustainable Development Goals (SDGs) for the benefit of our whole society.

Lunar dark mantle deposits: role of pyroclastics in understanding Explosive volcanism

Date

2023-12-08

Speaker

Mr. Dibyendu Misra

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Dark Mantle Deposits (DMD) constitute a distinct lunar lithological unit, primarily associated with the floor fractures of major mare-filled basins. These deposits have morphological characteristics of smooth homogeneous texture with relatively low albedo. DMDs are distinguishable from exogenic dark hallows mainly from morphological characteristics of non-circular shape, diffused boundaries, and alignment with volcanic features. DMDs contain pyroclasts in the form of partially crystallized droplets of Fe-bearing glasses that provide insights into explosive lunar volcanic eruptions and reveal the presence of volatile-enriched mantle resources. These pyroclastic deposits are further categorized into local and regional deposits based on their areal extent. Local pyroclastics are attributed to vulcanian-type volcanic activity whereas regional deposits are associated with strombolian or fire-fountain-type volcanism. The physical and compositional variations within local and regional DMDs contribute to a comprehensive understanding of the primary lunar mantle composition and evolutionary process of the Moon. The remote identification of volcanic glasses is challenging due to spectral overlap with lunar Fe-bearing minerals in the visible to near-infrared range. The high spatial resolution Moon Mineralogy Mapper global data coverage is used in this work to develop a methodology that can be used for the identification and characterization of localized and regional DMDs.The extensive study carried out at a few local and regional deposits will be presented and discussed.

Evidence of late irradiation from calcium aluminium-rich inclusions date

Date

2023-12-01

Speaker

Mr. Advait Prasad Unnithan

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Isotopic studies of meteorites exhumed excesses in specific isotope(s) of element(s), which were demonstrated to have originated from the decay of radionuclide(s). The Genesis of these parental short-lived now-extinct radionuclides (SLNs), having half-life in the range of a few days to millions of years, has been a subject of research investigation for decades. Several astronomical, observational, theoretical, and isotopic studies of meteorites suggest that our Sun, during its infancy (4.56 Ga years ago), was very active, resulting in several episodes of intense flaring with copious production of enhanced solar energetic particles. These solar energetic particles (SEPs), on interaction with ambient gas and dust in the early Solar system, can produce SLNs such as 7Be (t1/2=53 days), 36Cl (t1/2=0.3Ma), 26Al (t1/2=0.72Ma), 10Be (t1/2=1.38Ma), etc. These isotopes generated in the late stage (>5 Ma after the birth) irradiation events can get incorporated in the early solar system solids forming larger bodies, asteroids, planetesimals, etc. This late irradiation event is hypothesized to make a small but significant contribution to a few of these SLNs. Calcium-Aluminium rich Inclusions (CAIs), being one the first forming solids in the Solar system, are important suites of objects to understand the earliest history of solar system events and processes. Sodalite (Na8Al6Si6O24Cl2) and Wadalite (Ca6Al5Si2O16Cl3), chlorine (Cl) bearing metasomatically generated secondary minerals found in some CAIs have been studied for traces of SLN 36Cl.

Precision in Motion: Fabry-Perot Etalon as a Wavelength Calibrator for Extreme Precision Radial Velocity Methods

Date

2023-11-30

Speaker

Shubhendra Nath Das

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

In this talk, I will explore how the Fabry-Perot etalon is changing the game in making radial velocity measurements super precise. I will start by understanding why it's crucial to calibrate wavelengths and look at the qualities a good calibrator should have. I'll show you how the Fabry-Perot etalon meets these standards, comparing it with other methods and pointing out its amazing benefits. At the end I will wrap up by discussing the stability and instrumental needs of the Fabry-Perot etalon to meet expectations.

Phase Shift Measurement of Acoustic Waves in the Lower Solar Atmosphere

Date

2023-11-24

Speaker

Dr. Hirdesh Kumar

Venue

USO Seminar Hall

Abstract

Solar atmosphere provides a conducive environment for the generation, propagation, mode-conversion, and dissipation of various magnetohydrodynamics (MHD) waves. Acoustic waves are generated by compressibility, whereas the buoyancy-restoring force generates gravity waves. The acoustic waves generated inside the Sun's convection zone are trapped in the acoustic cavities and form standing waves. In the quiet-Sun photosphere, the cutoff frequency is 5.2 mHz, and low-frequency acoustic waves are evanescent. Utilizing the near-simultaneous photospheric and chromospheric line-scan observations in Fe I 6173 A and Ca II 8542 A, respectively, obtained from the Narrow Band Imager instrument installed with the Multi-Application Solar Telescope operational at USO, we have estimated seven height velocities within the Fe I line and nine height velocities within the Ca II line using the bisector method. The analysis of phase shift vs frequency and height shows a non-zero phase shift, indicating the non-evanescent nature of low-frequency acoustic waves in the quiet-Sun. In this talk, I will discuss the possible factors responsible for the non-evanescent nature of low-frequency acoustic waves.

Spectro-polarimetric Studies of Symbiotic Binaries

Date

2023-11-23

Speaker

Arijit Maiti

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Symbiotic stars are binary systems consisting of a red giant and a hot radiation source, usually a white dwarf. The cool giant star loses material via Roche lobe overflow or through its stellar wind, which flows onto the hot compact star, usually via an accretion disk. Symbiotic binaries are of particular interest to astronomers as they can be used to learn about stellar evolution. They are also vital in the study of stellar wind, ionized nebulae, and accretion because of the unique interstellar dynamics present within the system. However, not a great deal is known about the structure and dynamics of such systems. Spectro-polarimetric studies of such systems represent an excellent technique for probing their 3D morphology and internal dynamics. Of particular interest are the spectro-polarimetric studies of the two broad Raman scattered lines at 6825 and 7082 angstroms seen in the spectra of most symbiotic stars. In this talk, I shall discuss the basics of symbiotic star systems, their properties, and how spectro-polarimetric techniques help in probing such systems with particular emphasis on the diagnostic potential of the Raman scattering process. I shall conclude the talk by discussing how ProtoPol (a prototype spectro-polarimeter currently under development in PRL) with a medium resolution of (R ~ 7000) can help conduct such spectro-polarimetric studies.

Evolution of X-ray Instrumentation and Astronomy

Date

2023-11-10

Speaker

Neeraj Tiwari

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

X-ray astronomy, a latecomer in the field of observational astronomy, remained unexplored until the 1960s due to the inherent challenge of cosmic X-rays being unable to penetrate Earth's atmosphere. Since its inception, X-ray astronomy has undergone a remarkable evolution, reshaping our understanding of the cosmos. It began its journey with experimental X-ray observations using sounding rockets, then progressed to balloon-borne missions, and eventually to the deployment of advanced satellite-based observatories. This evolutionary path has illuminated the field of astronomy, revealing complex high-energy phenomena associated with black holes, neutron stars, and active galactic nuclei. X-ray astronomy has played a vital role in understanding the mysteries of accretion processes, supernovae, X-ray binaries, and gamma-ray bursts. It has also provided crucial insights into the formation and evolution of galaxies, the behavior of matter under extreme conditions, and the dynamics of celestial collisions. The pursuit of precision and clarity in X-ray observations was made possible through the evolution of technology over the last six decades, which led to the development of groundbreaking X-ray telescopes like Chandra, XMM-Newton, and NuStar. These missions owe their success and improved performance to the advancements in technology, enabling us to address long-standing questions within the field of astronomy. In this seminar, we will journey through the evolution of X-ray astronomy, exploring its inspiring history and the ways it has deepened our understanding of high-energy astrophysical processes. We will also explore the ongoing challenges in the development of the next generation of X-ray telescopes and the promising opportunities they hold for the future of this captivating branch of astronomy.

VLT/HiRISE: Direct characterization of young giant exoplanets at high spectral resolution

Date

2023-11-09

Speaker

Dr. Arthur Vigan

Venue

Online link : https://meet.google.com/mhu-ukug-gyy

Abstract

A major endeavor of this decade is the direct characterization of young giant exoplanets at high spectral resolution to determine the composition of their atmosphere and infer their formation processes and evolution. Such a goal represents a major challenge owing to their small angular separation and luminosity contrast with respect to their parent stars. Instead of designing and implementing completely new facilities, it has been proposed to leverage the capabilities of existing instruments that offer either high contrast imaging or high dispersion spectroscopy, by coupling them using optical fibers. In this seminar I present the implementation and first on-sky results of the HiRISE instrument at the very large telescope (VLT), which combines the exoplanet imager SPHERE with the recently upgraded high resolution spectrograph CRIRES using single-mode fibers. The goal of HiRISE is to enable the characterization of known companions in the H band, at a spectral resolution of the order of R = 100 000, in a few hours of observing time. I will present the science case, the main design choices and the technical implementation of the system, and the first performance assessment after commissioning.

Use of Bose symmetry to test symmetry violations

Date

2023-11-06

Speaker

Prof. Rahul Sinha

Venue

Room no: 469 (Main campus)

Abstract

We will show how Bose symmetry in heavy flavour decays can be used to study violations of CP, CPT and SU(3) symmetries

X-Ray Spectral Properties of Narrow Line Seyfert 1 galaxy

Date

2023-11-02

Speaker

Ms. Isha Mahuvakar

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Narrow-line Seyfert 1 (NLS1) galaxies are a subclass of Active Galactic Nuclei (AGN), showing relatively narrow width (FWHM < 2000 km s-1) of broad permitted emission lines in their optical spectra. These galaxies are supposedly powered with low mass supermassive black holes (105 – 107 Msun) and exhibit high accretion rates. In this seminar I shall present X-ray spectral properties of a NLS1 galaxy B3 1702+457 using multi-epoch XMM-Newton and AstroSAT observations. Our preliminary results show that the 0.3-10 keV X-ray spectra of this NLS1 can be fitted with an absorbed power law plus reflection component and Fe Ka emission line. We also find the evidence for absorption edges at soft energies. The multi-epoch X-ray observations hints for the flux as well as spectral variability. In this talk, I shall emphasize on the peculiarity of NLS1 X-ray spectral properties.

Geodynamic evolution of the Tharsis province Mars: insights from volcano-tectonic and fluvial landforms

Date

2023-10-27

Speaker

Dr Anil Chavan

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

I will talk about the volcano-tectonic and fluvial landforms of two different areas: Syria planum (south- east) and Koval’sky crater (south) of Tharsis province. The tectonic feature associated with the upwelling of the mantle from Noachian to the early Amazonian time bears distinctive characteristics of local and regional tectonism. New insight into the evolution of volcanic domes and associated fractures may be gained from the analysis of the ages of the tectonic and volcanic features. The number, total length, linear density of faults in the Syrian Planum region, and deformation rates are reported for each of the five stages of tectonism. 1076 Syria planum-related tectonic features, which are radial, tangential, and concentric to the center of the Syria planum, were assigned to one of these stages based on their stratigraphic and crosscutting relationships defined in the most recent geological map. The attribute of each stage indicates that the deformation rate in the early/middle Noachian, late Hesperian and in early Amazonian was lower, while it has acquired a pick in late Noachian to early Hesperian. It also shows well-established fluvial system draining towards north and subsequently went to the Echaus plateau. This study also focuses on the volcano-tectonic landforms on the southern limb of Tharsis province Koval’sky crater, and their interaction with the fluvial activity. Here, we analysed graben system in southern Tharsis province, which affected Koval’sky crater and accommodated a volcanic plug along one of the major graben systems on the eastern part of the impact. The volcanic plug within crater bears evidence of fluvial channels showing radial drainage patterns.

Investigation of Atmospheric Clouds and Boundary Layer over the Western-Indian Region

Date

2023-10-23

Speaker

Mr. Dharmendra Kumar Kamat

Venue

USO Seminar Hall

Abstract

Atmospheric clouds are crucial in the Earth’s hydrological cycle, radiation budget, and manifest regional and global weather conditions. The formation process of clouds starts in the lowest layer of the atmosphere (known as the Atmospheric Boundary Layer, ABL)and forms at heights ranging from a few hundred meters to several kilometers. Clouds are highly dynamic in space and time, and their proper representation in climate models remains challenging. The true representation of clouds in weather and climate models and a better understanding of physical processes governing cloud formation and dynamics are essential for predicting future climate. This seminar will discuss the cloud processes, cloud-boundary layer interaction, and different techniques for investigating clouds and ABL. Results derived using Lidar observations under the PRL’s Indian Lidar Network (ILIN) Programme over the three western-Indian regions (Ahmedabad, Mount Abu, and Udaipur) will be presented.

Multiwavelength study of hot and exotic stellar populations in star clusters

Date

2023-10-23

Speaker

Ms. Sharmila Rani

Venue

Online

Abstract

Star clusters are dynamically active stellar systems where interactions and collisions, especially involving binaries, are quite frequent and result in stellar exotica such as blue straggler stars (BSSs), cataclysmic variables, etc. Globular clusters (GCs), being old and dense, host low-mass stars in various stages of evolution, making them ideal for investigating the end stages of low-mass star evolution and the origins of exotic stellar populations, which are not yet fully understood. Ultraviolet (UV) studies conducted so far using HST and GALEX data have revealed the presence of intriguing stars, such as extreme horizontal branch (EHB) and blue hook (BHk) stars in GCs, making them enigmatic systems. Furthermore, the discovery of multiple stellar populations (MSPs) in both types of clusters through UV observations has provided new perspectives on their formation and evolution. We examined the properties of late-stage, UV-bright and exotic stellar populations in targeted star clusters using the multiwavelength data from the ground as well as space-based observatories. We primarily have employed the UV data from the Ultraviolet Imaging Telescope (UVIT)onboard AstroSat, India’s first multi-wavelength observatory, in both far-UV (FUV) and near-UV (NUV) bands. In this talk, I will present an in-depth analysis of four clusters, consisting of two intermediate-mass GCs (NGC1261 and NGC2298) and two open clusters (OCs) (NGC188 and NGC2818). We constructed the UV-optical colour-magnitude diagrams (CMDs) for member stars and compared them with theoretical isochrones to probe the multiple population phenomenon in GCs. Furthermore, based on the atmospheric parameters estimated using the SED fitting technique, we constrained the formation scenarios of the hot horizontal branch (HB) and exotic stars in clusters. Additionally, FUV imaging analysis of a Planetary Nebula (PN) within the field of OC NGC2818 strongly suggests its membership in the cluster, offering a unique opportunity to test stellar evolution models.

How radio techniques can give insights into solar eruptions

Date

2023-10-20

Speaker

Dr. Anshu Kumari

Venue

USO Seminar Hall

Abstract

The coronal magnetic field (B), the ultimate driver of space weather, plays an essential role in the formation, evolution, and dynamics of the small and large-scale structures in the solar corona. These structures lead to gigantic explosions in the solar atmosphere in the form of large-scale eruptions, such as coronal mass ejections (CMEs), which may severely impact near-Earth space. CMEs are often accompanied by radio emissions, which provide access to observations of the related solar, heliospheric, and ionospheric space weather phenomena. Radio techniques can provide early signatures of particle acceleration associated with solar flares and CMEs. In this seminar, I will talk about state-of-the-art ground and space-based radio instrumentation for solar and space weather studies. Using radio observations and time-dependent data-driven numerical modelling of active regions, I study the formation and eruption of the coronal flux ropes. I will highlight the radio techniques to constrain the initial CME properties close to the Sun and the numerical modelling approach to understand the initiation and evolution of large-scale solar eruptions.

Lunar elemental abundance estimation based on Chandrayaan-2 class and Chandrayaan-1 moon mineralogy mapper datasets

Date

2023-10-20

Speaker

Dr Megha Upendra Bhatt

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The mapping of refractory elements at local and global scales is an important tool for revealing the petrological characteristics of the Moon and for understanding its geological evolution. The direct approaches (X-ray and Gamma ray spectroscopy) mainly provide elemental abundances at spatial resolution of tens of kilometers. In contrast, the indirect approaches (UV-VIS-NIR spectroscopy) provide spatial resolution of tens to hundreds of meters but they are influenced by space-weathering and topographic effects and majorly based on empirical relationships between band parameters and the chemical composition of returned samples. Chandryaan-2 Large Area Soft X-ray Spectrometer (CLASS) data from Chandrayaan-2 mission as ground truth to estimate major refractory elements for understanding the petrological characteristics of the Moon. The algorithm uses multivariate regression between CLASS derived elemental abundances from selected regions spread over mare and highlands and spectral parameters derived using the nearly global coverage of the Moon obtained by the Moon Mineralogy Mapper (M3). The results will be discussed are based on a comparative analysis considering independent techniques applied on regional and global scales.

An initiative to explore the life beyond Earth at Amity Center of Excellence in Astrobiology

Date

2023-10-13

Speaker

Dr Sneha Arunkumar Gokani, Ramanujan Fellow, Amity University Maharashtra, Mumbai

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

We have been involved in the development of the two biological payloads Amity space biology experiment (ASBE) and the Amity life growth experiment (ALGE). The center has been actively been involved in field exploration studies in the analogues regions of Ladakh by bringing together scientists working in the areas of Astrobiology and space sciences from India and Abroad. The centers explored the surface and subsurface of this regions as well as isolated extremophiles from the above said regions. Amity has also developed a rover Mars Amity Surface Characterization and Operations Trainer (MASCOT-1). This was a prototype and can be used as a platform for setting up of mars exploration instruments. Our center has also collaborated with Berkeley SETI Research Center at University of California Berkeley to conduct India’s first search for advanced extraterrestrial life. The program aims to develop novel tools utilizing state-of-the-art strides made in field-programmable gate arrays for high-speed data capture from existing and upcoming radio telescopes. Our expertise also extends to modeling and simulation of hydrothermal systems, impact craters and planetary analogue studies. With the aim of studying the microgravity effects on plant samples, our students are developing a Random Positioning Machine (RPM). Apart from this, we also work on space weather aspects on Earth specifically; our work focuses on the investigation of geomagnetic changes that take place during transient solar eruptions. We have carried out the statistical study on exploring the possibility of reduced geoeffectiveness of solar cycle 24. In addition to that, studies related to dependence of different solar drivers on the outer radiation belt energetic electron depletion is carried out. The details of the above works will be presented during the seminar.

On the nature of AGN in dust-obscured galaxies

Date

2023-10-12

Speaker

Abhijit Kayal

Venue

Thaltej Seminar room (113)

Abstract

We explore the nature of Active Galactic Nuclei (AGN) hosted in high-redshift (0.59 <= z <= 4.65) dust-obscured galaxies (DOGs) by performing X-ray spectral study of DOGs detected in the XMM-SERVS deep field. The X-ray spectra fitted with a simple absorbed power law plus reflection component or with a torus-based reflection model reveal that a substantial fraction (30 per cent) of our sample DOGs are heavily obscured (N_H > 1023 cm-2) AGN. The absorption-corrected 2.0 - 10 keV X-ray luminosity suggests them to be luminous quasars. The NH versus Eddington ratio diagnostic plot infers that our DOGs host a heterogeneous population of AGN containing heavily obscured AGN as well as reddened quasars. We find that only a few of our sources are likely to belong to an early phase during which accretion and obscuration peak, while the remaining sources possibly belong to a late phase during which radiative feedback from dominant AGN blows away obscuring material. Since X-ray detection is limited only to bright AGN, we also use deep multi-frequency radio continuum surveys, which help us to unveil a large fraction of low-luminosity AGN hosted in DOGs. In this talk, I shall emphasize the importance of deep radio surveys to uncover the obscured population of AGN.

Interplanetary Coronal Mass Ejections

Date

2023-10-09

Speaker

Ms. Binal Patel

Venue

USO Seminar Hall

Abstract

Interplanetary coronal mass ejections (ICMEs) are interplanetary manifestations of CMEs. ICMEs are essential to study as they are attributed to various space weather phenomena such as solar energetic particle (SEP) events, interplanetary (IP) shocks, and geomagnetic storms, etc. An interesting subset of ICMEs have enhanced magnetic fields (>10 nT) that rotate slowly through a large angle, low proton temperatures, and low plasma Beta; (ratio of the thermal and magnetic field pressure) are called as magnetic clouds. Magnetic clouds are often termed interplanetary magnetic flux ropes (IMFR). There are clear evidences that magnetic clouds are the drivers of intense geomaganetic storms. Hence, understanding the geometry of the magnetic clouds at 1 AU is crucial for analysing their interaction with Earth’s magnetosphere. In this talk, I will discuss the physical connection between the IMFRs at near-Earth enviornment and corresponding CMEs at the near-Sun region by comparing the magnetic field structures of IMFRs and CME source regions. We attempt to identify the flux rope structure in 18 selected events that occurred during Solar Cycle 24 by fitting models with a cylinder and torus magnetic field geometry, both with a force-free field structure. Our results show that the observed flux rope parameters are well reconstructed with the models. The helicity signs of the magnetic clouds remain conserved during their Sun-Earth transit. Our results further support the idea that a flux rope with the main axis parallel to the PIL erupts in a CME, and the erupted flux rope propagates through the interplanetary space with its orientation maintained and is observed as an IMFR.

IDP in Solar System: Observations, Results and Research Opportunities

Date

2023-10-06

Speaker

Dr Jayesh P. Pabari

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

Interplanetary Dust Particles (IDPs) are found everywhere in solar system. The dust is an important constituent in the formation of solar system. The IDP may originate from sources like Asteroid belt, Kuiper belt and comets. They evolve dynamically in the solar system under the effect of various forces. Though there are some measurements of IDP near Earth and also, in the interplanetary space; the flux and other parameters of IDP at some planets are not understood fully. Further, the dust particles in the solar system may enter a planetary object and affect it in different ways. The speaker will convey observations, results and research opportunities related to IDP in solar system.

Accretion Disk-Corona Connection in Active Galactic Nuclei

Date

2023-10-05

Speaker

Dr. Indrani Pal

Venue

Online

Abstract

One of the important components of active galactic nuclei (AGN) is the corona, believed to be responsible for the luminous X-ray continuum that is observed in the radio-quiet category AGN. The hot electrons within the corona Compton up scatters the optical and UV photon from the accretion disk to X-ray energies. In spite of the corona being considered an integral part of AGN, much is still unknown about its nature, geometry, location and physical properties. Using data taken from X-ray telescopes such as the NuSTAR and XMM-Newton, a systematic investigation was carried out on the nature of the corona using X-ray spectral techniques. On analysis of a sample of about 100 Seyfert type AGNs, the coronal temperature could be constrained for about 75 AGN. Of these, variation in the temperature of the corona was found in two. Though spectral fits could provide us with important characteristics of the corona, a key unknown is the geometry, which could be constrained using X-ray polarization observations. Using X-ray polarization data from the Imaging X-ray Polarimetry Explorer (IXPE), launched by NASA in December 2021, we could constrain the geometry of the corona in IC 4329A, one among the four radio-quiet AGN for which IXPE observations are available as of today. Details of the results on the coronal properties of AGN obtained from our systematic investigation, as well as plans for the future will be presented.

Chandrayaan-2 XSM: Bits and Bytes to Science Data Archive

Date

2023-10-04

Speaker

Mithun N. P. S

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Data acquired by various astrophysical observatories are generally made available to the scientific community worldwide often after a short proprietary lock-in period for the instrument team or the proposers of the observations. Such open data policies have played an important role in advancement in our understanding of various astrophysical processes through archival data analysis. While the data policies of ground based observatories differ, almost all space based observatories, which are often fully funded by public money, are required to make the data public with varying lock-in periods. However, the usability of the archival data crucially depends on how well the data archive is prepared and documented. It is also essential to provide the users with analysis tools that apply required corrections and calibration to the observational data which in most cases are quite involved. The Solar X-ray Monitor (XSM) of the Chandrayaan-2 mission has been observing the Sun from lunar orbit and providing measurements of soft X-ray spectra of the Sun for just over four years now. The raw data acquired gets downloaded at designated passes over Indian Deep Space Network (IDSN) at Bylalu, Bangalore. The data then undergoes initial processing at Indian Space Science Data Centre (ISSDC) after which it is made available to the Payload Operations Center (POC) at PRL. Higher levels of data processing and validation are carried out at PRL and the final data archive is hosted at ISSDC PRADAN portal. PRL also maintains an interactive website for users to examine the XSM light curves. This entire chain from data reception to data archival and updating of the website is automated with a suite of software tools that we call as XSMDMS: XSM Data Management System, which in turn uses the XSM Data Analysis Software. In this talk, I will discuss how the XSM data makes its way from bits and bytes to the science data archive.

Investigation of geologically complex chloride-rich terrain on Mars and

Date

2023-09-29

Speaker

Dr Deepali Singh

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

This work involves the exploration of chloride-rich terrains on Mars to understand their origin since their hygroscopic nature enhances their potential to sustain life as compared to other minerals. We aim to reconstruct the geological evolution of one such area and examine the habitability potential of the area when the conditions on Mars became unconducive. In this context, we have investigated a topographic depression within the Terra Sirenum region, one of the largest chloride deposits on Mars. Morphological examination of the area showed that its floor is covered with bright-toned polygons, and while the area near its boundary is rich in Fe/Mg and Al-phyllosilicates, the centre consists of chlorides with a possible mixture of sulfates. The chlorides within the basin were dated back to the Hesperian and imply the weathering of chloride-rich rocks and their transportation to the basin, which gradually desiccated. We have estimated the amount of chloride present and used Einstein's parameter for sediment discharge to determine the duration for which the area was hydrological active. We have further modelled our findings to ascertain the habitability potential of the area.

Contribution of Radio Occultation (RO) Measurements to the Understanding of the Venus Atmosphere

Date

2023-09-19

Speaker

Dr Janusz Oschlisniok, Rheinish Institute for Environmental Research, Dep. Planetary Research, Cologne, Germany

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

In RO measurements a spacecraft which in orbit around Venus sounds the atmosphere of the planet with radio waves. Those are recorded at ground station on Earth. Information about Venus’ atmosphere are achieved from observed changes in the signal phase and amplitude. While the phase shift is used to derive atmospheric profiles of temperature, pressure and number density, the additional variation of the signal power is used to derive the mixing ratios of trace gases like SO2 and H2SO4. Since the derived atmospheric profiles cover the altitude range between about 35 and 80 km altitude, RO measurements provide crucial information to the understanding of the atmospheric state and dynamics.

Mineralogical characterization of hot spring deposits and stromatolites from Martian analog perspective

Date

2023-09-15

Speaker

Dr Subham Sarkar

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

Stromatolites are often regarded as the oldest evidence of life on Earth, and hot springs are thought to be one of the critical locations for the emergence of early life on Earth. Thus, from a Mars science perspective, which has shifted to search for biosignature in recent years, substrates with higher biogenicity have become more relevant for terrestrial-based analog studies. The study includes a thorough examination of terrestrial stromatolites, including their geological background, environmental niche, petrography, mineralogy, and rare earth element geochemistry. The Mesoarchean (>2.5 Ga) Mfolosi Stromatolites of Pongola Supergroup, Kaapvaal Craton, South Africa, are identified as a probable Martian parallel and share similar characteristics to Gusev Crater, Mars. Based on petrography, mineralogy, spectroscopy, and geochemistry, this work discusses the geomorphological context and significance of hydrothermal activity with terrigenous inputs within a peritidal context and thus offers insight into its genesis likely to be relevant in the once existed ocean shore on Mars. Additionally, the hydrothermally-fed Tapovan hot spring in Uttarakhand, India, could be another potential Mars equivalent. This study explored hydrothermal assisted secondary minerals, which include calcium carbonate, Fe-bearing phases, and Fe-/Mg-smectites, similar in line with what was recently detected by Perseverance at the floor of Jezero Crater using advanced spectroscopy and X-ray diffraction techniques. This discovery has significant implications for astrobiological research, providing insights into the putative biosignatures and the paleoenvironmental conditions of Mars, thus assisting in the search for extinct/ extant life on the red planet and beyond.

Introduction to Gamma Ray Bursts (GRBs)

Date

2023-09-14

Speaker

Ashish Kumar Mandal

Venue

Seminar Room # 113/114 (Thaltej campus)

Abstract

Gamma Ray Bursts (GRBs) are short, intense flashes of gamma rays coming from deep space. They were first discovered (in 1967) by VELA military satellites of the USA launched to govern the 1963 nuclear test-ban treaty. They are observed across the electromagnetic spectrum, from radio to very-high-energy gamma rays. At present, space-based observatories detect, on average, approximately one GRB per day. The extensive observational and theoretical efforts have confirmed them as highly relativistic explosions, confirmed their distance scale, pinpointed their host galaxies, identified the systems that create them and opened them as astrophysical probes throughout the Universe. GRBs are now a major astrophysical tool to probe the final stages of stellar evolution and the creation of supernovae, to examine the creation and propagation of relativistic jets and their impact on the Universe at large, and to use as indicators to identify galaxies across cosmic time-some in the earliest epochs of Universe. The extreme nature of both their progenitors and emission mechanisms makes them the most promising sources for joint electromagnetic and gravitational wave detection. This is demonstrated by the recent (2017) detection of gravitational waves (GW170817) and short GRB (GW170817A) from a merger of the double neutron-star binary system. In this seminar, I will talk about the brief history of GRBs, their observations and properties, different dedicated GRB missions, detection methods, understanding so far, etc., and finally, I will connect you to my work.

Design and development of Venus Orbiter Dust EXperiment (VODEX)

Date

2023-09-08

Speaker

Sonam Jitarwal

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

In the solar system, the interplanetary dust particles (IDPs) originate from the asteroid belt, comets, Kuiper belt and a few other minor sources. During their evolution, they may undergo collision and evaporation or get ejected from the solar system depending on their size and properties. These IDPs are nanometer to micrometer-sized dust particles travelling at hypervelocity, i.e. greater than one km/s. We are developing an Impact Ionization dust detector to study the interplanetary dust particles for future Venus orbiter missions. The signal generated by the dust particle's impact on the detector's target plate is measured, and using its rise time and peak voltage, the particle's physical properties, i.e., mass, velocity and flux, will be derived. In this talk, I will discuss the design, development and testing results of VODEX electronics along with the testing results using a nano-second pulse laser. Also, different types of electronics noise, signal-to-noise ratio calculation, and preliminary thermal analysis results will be discussed.

Intra-night optical variability of radio-quiet narrow-line Seyfert-1 galaxies

Date

2023-09-04

Speaker

Dr. Vineet Ojha

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Variability studies of Active Galactic Nuclei (AGNs) play a powerful diagnostic tool in understanding the physical processes occurring in objects that are unresolved by direct imaging with currently available techniques. Here, we report the first attempt to systematically characterize intra-night optical variability (INOV) for a sample of seven radio-quiet and/or radio-silent narrow-line Seyfert 1 galaxies (RQNLSy1s) that had shown recurring flaring at 37 GHz in the radio observations at Metsähovi Radio Observatory (MRO), indicating the presence of relativistic jets in them, but no hints of jets in the recent radio observations of Karl G. Jansky Very Large Array (JVLA) at 1.6, 5.2, and 9.0 GHz. A total of 28 intra-night sessions, each lasting > 3 h, was conducted with 1-2.5m class telescopes of ARIES and PRL for the INOV study of this sample. The resulting level of INOV from this sample is found to be statistically comparable to those observed in γ-ray-detected radio-loud NLSy1s (MBH ∼ 10^7 M⊙ ), that display blazar-like INOV. Thus, it appears that even lower-mass (MBH ∼ 10^6 M⊙ ) RQNLSy1 galaxies can maintain blazar-like activities. Furthermore, based on the optical behavior of these seven RQNLSy1s, we infer that INOV from the current sample of RQNLSy1s could be either due to a twisted in-homogeneous jet or magnetic re-connection in the magnetosphere of the black hole. In this talk, I will also discuss the optical study of the most distant gamma-ray-detected NLSy1 (z = 1.344), whose observations were taken from the PRL 2.5m telescope.

Highlights of the sessions from the Asia Oceania Geosciences Society 20th Annual Meeting (AOGS2023)

Date

2023-09-01

Speaker

Sachana A S, and Ambily G

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

The 20th Annual Meeting of the Asia Oceania Geosciences Society (AOGS) was held at Suntec, Singapore, between 30th July and 4th August 2023. In this seminar, we shall be presenting an overview of the discussions carried out during the conference. We shall also discuss the work we presented at the conference.

Comet Observations from the 3.6m Devasthal Optical Telescope (DOT)

Date

2023-08-31

Speaker

Goldy Ahuja

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

This talk presents the results from the first observations of comets using the ADFOSC (ARIES Devasthal Faint Object Spectrograph and Camera) on the 3.6m Devasthal Optical Telescope (DOT). The famous green comet C/2022 E3 was observed post-perihelion on 16 Feb and 22 Feb 2023. The talk will focus on the challenges faced during the reduction and calibration of the data from the ADFOSC spectrograph. The procedures for reducing the data will be discussed, and the production rate ratio will be presented and compared with results from the TRAPPIST group.

Development of Spectro-polarimeters for PRL Telescopes

Date

2023-08-28

Speaker

Arijit Maiti

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Polarization measurements in astronomy is one of the most challenging observational techniques given its photon-hungry nature. While imaging polarimetry in broadband filters have been a very successful technique to explore a variety of astro-physical situations, Spectro-polarimetry is rather rare, and not so many instruments available to explore this domain. Spectro-polarimetry is the study of polarization profiles of various features in the spectrum of any astro-physical object. Measuring the wavelength dependence of the polarization of radiation from such sources can reveal valuable and interesting constraints on the nature of objects observed. Here at PRL, we are in the process of developing two such instruments having spectro-polarimetric capabilities. Mt. Abu Faint Object Spectrograph and Camera–Echelle Polarimeter (M-FOSC-EP) is a 2-channel multimode instrument equipped with a low-resolution spectroscopic and imaging arm and an intermediate-resolution (R~15000) spectro-polarimetric arm. As a precursor to this instrument, a prototype spectro-polarimeter called ProtoPol has also been designed, using completely off-the-shelf optical components, for medium-resolution (R~6000) spectro-polarimetric studies. In this seminar, I will talk about the basics of the technique of spectro-polarimetry and a few science cases that could be benefitted from it. I will talk about the design and specifications of both instruments and share the latest assembly status of ProtoPol which currently is in the development stage. I will also discuss a simulation code that is being developed to simulate the performance of the M-FOSC-EP instrument.

Highlights of the sessions from the Asia Oceania Geosciences Society 20th Annual Meeting (AOGS2023)

Date

2023-08-25

Speaker

Ms Neha Panwar

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

The 20th Annual Meeting of the Asia Oceania Geosciences Society (AOGS) was held at Suntec, Singapore, between 30th July-4th August 2023. In this seminar, we shall be presenting an overview of the discussions carried out during the conference. We shall also be talking about the work that we presented at the conference.

Chemical Analysis of Nearby M Dwarfs Based on High-resolution Near-infrared Spectra Obtained by the Subaru/IRD Survey

Date

2023-08-24

Speaker

Dr. Hiroyuki Tako ISHIKAWA

Venue

Online

Abstract

Chemical analyses of M dwarfs are scarce but necessary to explore the formation scenario and internal structure of planets orbiting them. I will talk about our spectral analyses of 71 mid- to late M dwarfs (2800 < Teff < 3400 K) observed in the Subaru/IRD planet search project (IRD-SSP survey). We used the high-resolution (∼70,000) near-infrared (970–1750 nm) spectra to measure the effective temperatures and the abundances of Na and Fe by the line-by-line analysis based on model atmospheres. For 13 objects of the targets, we also measured elemental abundances of Mg, Si, K, Ca, Ti, V, Cr, Mn, and Sr. The radial velocities we measured from the spectra were combine with Gaia astrometry to calculate the Galactocentric space velocities UVW. While the [X/Fe] distributions are comparable to those of nearby FGK stars, most of which belong to the thin-disk population and the most metal-poor object, Barnard's Star, could be a thick-disk star. The UVW velocities also support this. The results raise the prospect that near-infrared spectra of M dwarfs obtained in the planet search projects can be used to grasp the trend of elemental abundances and the Galactic stellar population of nearby M dwarfs.

Characterisation of Dust Detector Using Software Simulations

Date

2023-08-18

Speaker

Mr Srirag Nambiar

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

Asteroids in the belt between Mars and Jupiter, on collision, generate immense amounts of smaller dust particles. Comets leave out dust and gas when they move closer to Sun. In the size range of nanometers to millimetres, these particles undergo a dynamic evolution within the Solar system under the effect of different forces. By studying the present distribution, we can better understand the source, the particle’s evolution and the effect of different forces acting on the particles. Impact ionization dust detectors have been utilised for in-situ analysis of such particles, which have provided excellent results and improved our understanding of these tiny particles. We at PRL are also developing such a dust detector aimed at future planetary missions. Optimizing the configuration for the best performance of such an instrument becomes important. In this talk, I will be discussing different types of detectors used for studying these particles and simulations carried out using SIMION, a software package used to simulate the trajectory of charged particles under a static electric field. It is used to compare and optimize the voltage bias configuration of the detector. In interplanetary space, other than dust particles, the detector will encounter solar wind particles, GCR and radiation belt particles. GEANT4 toolkit is utilised to estimate the noise generated due to such particles and radiation. Results of computation carried out for an Earth orbit will be presented.

Spectral Ages of Remnant Radio Galaxies

Date

2023-08-17

Speaker

Dr. Sushant Dutta

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The cessation of active galactic nucleus (AGN) jet activity can be well detected in radio galaxies with characteristic features such as absent core and jets, amorphous lobes of low-surface-brightness and strong spectral curvature. Radio galaxies with no AGN-jet activity are known as remnant radio galaxies (RRGs) which are believed to be rare objects. The scarcity of RRGs can be explained with the fact that they can be observed only over a relatively short time-window before they fade away due to radiative and dynamical energy losses. The time-scales of the active phase, remnant phase and AGN duty cycle are vital to understand the evolution of radio galaxies and related feedback. I shall present our ongoing work on estimating spectral ages of RRGs by modelling their radio spectral distributions (SEDs) with physically motivated models, namely, continuous injection (CION) and continuous injection-off (CIOFF) models. For our RRGs, we have obtained densely sampled SEDs across 144 MHz - 1.5 GHz using multi-frequency radio observations from LOFAR, uGMRT, MeerKAT and VLA. In this talk, I shall emphasize on the importance of newly acquired radio observations at band-3 (300-500 MHz) and band-4 (550-850 MHz) from uGMRT and L-band from MeerKAT, carried out under the superMIGHTEE and MIGHTEE projects respectively, which help us in placing better constraints on the spectral age estimates.

DWARF NOVAE: ACCRETION POWERED COSMIC FIREWORKS

Date

2023-08-14

Speaker

Akash Sundriyal

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

A dwarf nova outburst is a very special and characteristic event undergone by a cataclysmic variable. These events are associated with the accretion disc as confirmed by recent observations. During a dwarf nova episode, the accretion disc brightens up by 2-5 magnitudes in typically a few days. This is a result of enhanced accretion onto the white dwarf as the disc becomes unstable. These events typically last for 2-20 days and occur semi-regularly. In this talk, I will briefly cover dwarf nova phenomenon and the mechanism responsible for it. The effect of mass-transfer rate and its role in shaping the outbursts will also be discussed. I shall also discuss the SED and TESS light curve analysis that has been carried out for the long-orbital period system V1948 Cyg.

Mechanical and Electronics design and development of Sun Tracking system for 2m dish antenna.

Date

2023-08-04

Speaker

Vaibhav Jain, Ketan Agarwal, Hariom, and Yogesh Tailor

Venue

USO Seminar Hall

Abstract

Modeling the Ion Chemistry in The Coma of 67P/Churyumov-Gerasimenko

Date

2023-08-04

Speaker

Ms. Sana Ahmed

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Comet 67P/Churyumov-Gerasimenko (67P/C-G) was the target of the ESA’s Rosetta mission that orbited in its vicinity for nearly 2 years. Rosetta carried a suite of instruments that provided in situ measurements of the neutral and ionic species in the gas phase coma. The species that were detected include the primary ions H2O+, CO+, NH3+, CH3OH+, CH4+ and C2H4+ that is mainly formed by the photoionization of parent molecules. The protonated forms of parent molecules that were detected include H3O+, HCO+, NH4+, HCNH+ and CH3OH2+. The continuous monitoring of the coma of 67P/C-G also led to measurements of neutral molecules during the entire mission period. While the relative abundances of neutral molecules can be converted to absolute values, it is difficult to know the absolute ion densities in 67P/C-G. We use a combined chemical-hydrodynamical multi-fluid model in order to understand the ionic composition and the coma chemistry in 67P/C-G. Our coma model is based on fluid conservation equations; it employs an extensive chemical network and uses the neutral gas production rates as inputs. Using the neutral gas production rates reported in the literature, we have modelled the coma of 67P/C-G at different heliocentric distances. We use our model outputs to make a quantitative analysis of the major ion creation and destruction processes at various orbital locations of 67P/C-G. We note that high proton affinity species such as NH4+ and CH3OH2+ have the highest abundances in the coma. The abundance of primary ions can be correlated to their parent molecule abundance in some parts of the coma. The H3O+/H2O+ ratio may be used to comment on the extent of ion-neutral chemistry. In this talk, I will give an overview of the coma observations by Rosetta, and discuss my model results on the ion composition and chemistry occurring in the coma of 67P/C-G.

Automatic Learning for the Rapid Classification of Events: ALeRCE

Date

2023-08-03

Speaker

Amelia Bayo

Venue

Online

Abstract

Arguably, time domain (probably together with multi-messenger astronomy) is bound to change both, the way we "do observational astronomy" and what we know (and do not know) about the universe. Infrastructure like the Vera Rubin Observatory (VRO), for instance, will soon provide us with a much more dynamic view of a large portion of the night sky. The degree to which that kind of view can be scientifically exploited will heavily depend on our ability to generate more efficient data-flows and analysis tools, and the access to the right mid-size infrastructure for follow up. The Zwicky Transient Facility (ZTF) has been and is being used to test, improve, and prepare ourselves to deal with large data streams. All seven community brokers that will provide access for the general community to interesting variable objects detected by VRO are taking ZTF as the "training ground". In this talk I will present the work done by ALeRCE in particular (the only southern hemisphere broker) and how their services can provide a very interesting curated set of sources to be followed up by facilities related to your institute.

Ionic emissions in Comet C/2020 F3 (NEOWISE)

Date

2023-07-31

Speaker

Dr. Aravind K

Venue

Room No. 113/114, Thaltej Campus, PRL

Abstract

The composition of molecular Nitrogen relative to CO and H2O has been sparsely studied in comets. The abundance of these neutral gases in the coma can be probed using optical spectroscopy only via their ionic emissions. While detecting and analysing them is crucial, it is equally challenging due to their very low density. Even though the Great Comet of 2020, C/2020 F3 (NEOWISE), has been studied in detail via very high-resolution spectroscopy, the presence of ionic emissions has not been reported in it. Long slit low-resolution spectroscopy of such bright comets can help analyse the spatial profile in great detail. This seminar will discuss the detection of the ionic emissions N2+, CO+, CH+ and H2O+, along with a few unidentified and unusual emissions in the spectacular comet C/2020 F3 (NEOWISE). While the computed relative abundances and their implications will be discussed, we also try to compare the unusual emissions observed in comet C/2020 F3 with the emissions which were also seen in the spectrum of comet C/1987 P1 (Bradfield) but remained unnoticed at the time.

Silicon Carbide/Diamond Electronics for extreme environments

Date

2023-07-28

Speaker

Dr Narasimha Murty

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Silicon (Si) based electronics dominated the electronics industry for over seven decades. However, there are niche applications where the electronics is exposed to extreme conditions such as high temperatures, radiation environments, operation in liquid ambients where the conventional Is-electronics may not operate reliably. In this talk, the limitations of Si-electronics for extreme environments will be discussed. Potential wide-bandgap semiconductors such as Silicon Carbide (SiC), Diamond for operation under such harsh environments will be highlighted. Finally, the current technology, state-of-the-art and limitations of a SiC/Diamond will be covered.

Observations of Solar Corona Using Ground and Space-based Facilities

Date

2023-07-27

Speaker

Dr. Sasikumar Raja

Venue

USO Seminar Hall

Abstract

Shock induced dust formation in novae

Date

2023-07-27

Speaker

Dr. Ruchi Pandey

Venue

Room No. 113/114, Thaltej Campus, PRL

Abstract

Novae are the only objects in which it has been possible to observe directly all aspects of circumstellar dust formation on a frequent basis. Novae dust forms within a short time frame of typically 30 to 100 days after an outburst, allowing them to serve as test beds for understanding the formation and evolution of astrophysical dust. However, dust formation in the hostile environment of novae ejecta has been an open question for many decades. Several attempts have been made to understand the physical and chemical conditions required to dust formation in novae ejecta and its relation with the observable parameters. To explain the mechanisms underlying dust formation, numerous hypotheses have been proposed. In recent years, an intriguing hypothesis involving shock-induced formation of dust in novae has been proposed. A recent study of Nova V2891 Cyg by a PRL team provides, most likely, the first observational evidence of such a method of dust formation in novae ejecta. This seminar will commence with a concise introduction to the phenomenon of dust formation in novae, highlighting its significance and the current gaps in knowledge. Further, we will present the phenomenological cloudy modelling of Nova V2891 Cyg in order to illustrate the origin of some observational signatures of shock-induced dust formation.

Coronal Mass Ejections: From Observations to Simulations

Date

2023-07-21

Speaker

Dr. Anshu Kumari

Venue

USO Seminar Hall

Abstract

The coronal magnetic field (B), the ultimate driver of space weather, plays an essential role in the formation, evolution, and dynamics of the small and large-scale structures in the solar corona. These structures lead to gigantic explosions in the solar atmosphere in the form of large-scale eruptions, such as coronal mass ejections (CMEs), which may severely impact near-Earth space. CMEs are often accompanied by radio emissions, which provide access to observations of the related solar, heliospheric, and ionospheric space weather phenomena. Radio techniques can provide early signatures of particle acceleration associated with solar flares and CMEs. Using radio observations and time-dependent data-driven numerical modeling of active region, I study the formation and eruption of the coronal flux ropes. I will highlight the radio techniques to constrain the initial CME properties close to the Sun and the numerical modeling approach to understand the initiation and evolution of large-scale solar eruptions. I will also talk about state-of-the-art ground and spaced-based radio instrumentation for solar and space weather studies.

The Study of organic matter in Meteorites

Date

2023-07-21

Speaker

Ms Shreeya Natrajan

Venue

Seminar Room # 113/114 (Thaltej Campus

Abstract

The 23rd National Conference on Atomic and Molecular Physics was conducted at IIST in collaboration with Indian Institute for Science Education and Research (IISER), Thiruvananthapuram, Space Physics Laboratory (SPL), Thiruvananthapuram and Space Program Office (SPO), Bengaluru. Along with several posters and presentations, the conference had an exciting brainstorming session on “Origin of molecular life in space: new frontiers”. In this talk, I will present a brief overview of the discussions conducted during the conference and brainstorming session, along with a gist of my poster titled “Carbon nitrogen analysis of insoluble organic matter in meteorites”.

Unravelling the Origin Mystery of anomalously large lithium in red giants

Date

2023-07-20

Speaker

Prof. Eswar Reddy

Venue

Room No. 113/114, Thaltej Campus

Abstract

In general, lithium gets destroyed in stars as they evolve. However, a small group of stars show excess lithium and, in some cases, more than the abundance seen in their natal clouds. The problem remained a puzzle for more than 40 years. With the availability of high-quality spectra for a large number of stars and asteroseismic data, we could now locate the source of high lithium abundance in red giants. In this talk, I will discuss and provide the current understanding of the origin of high Li in stars.

The Giant Molecular Cloud G148.24+00.41: Gas Properties, Kinematics, and Cluster Formation at the Nexus of Filamentary Flows

Date

2023-07-20

Speaker

Mr. Vineet Rawat

Venue

Room No. 113/114, Thaltej Campus

Abstract

Giant molecular clouds (GMCs) are the cradles of young star clusters in which most stars form. Massive to intermediate-mass clusters play an important role in the evolution and chemical enrichment of the Galaxy through radiation and winds. However, the formation mechanism of stellar clusters, in particular, intermediate to massive clusters, is still not clear and a topic of debate. Determining and evaluating the physical conditions, kinematics, structures, and dynamics of massive molecular clouds (>10^5 Msun;) at their initial stages of evolution, such that stellar feedback effects are not significant there, are key to understanding the formation of stellar clusters. In this talk, I will present a case study of one such GMC, G148.24+00.41 having mass ~ 10^5 Msun; and size ~20 pc, based on CO molecular line data to understand its cluster formation scenario. I will present the role of filamentary flows in assembling the gas at the central gravitational potential of the cloud. I will discuss about the massive cluster formation scenarios given in the literature and their possibility in the G148.24+00.41 cloud.

Human Impact on Global Climate Change Over the Past Two Centuries: Use of Isotope-Tracing Techniques

Date

2023-07-19

Speaker

Prof. Mark Baskaran

Abstract

The human impact on global climate change over the past two centuries is unprecedented. An incredible growth of population, from 1.5 billion in 1900 to 7.9 billion today has led to an increase in energy consumption by more than 1000% over ~70 years to power the development. Never in the history of the Earth has such a drastic increase in the atmospheric CO2, from 296 ppm in 1900 to 423 ppm in 2023, took place; it is attributed to energy extraction from non-renewable resources (e.g., fossil fuel) contributing ~85% of total energy consumption. The ‘science of the changing environment’ is at the forefront of human endeavor and a significant (and increasing) fraction of the global GDP is currently being spent on addressing this science (e.g., increasing spatial extent of harmful algal blooms, ocean acidification, ever increasing number of micro-plastics in fresh and saltwater systems, weather-related catastrophic events, etc). Isotopes of key chemical elements have been widely utilized to identify and quantify recent environmental changes. In this talk, a set of case studies, illustrating global environmental changes in different regions of global oceans will be presented.

Thermophysical property of Martian Gale crater region: Implications for active dust deposition phenomenon

Date

2023-07-14

Speaker

Ms Farzana Shaheen, BIT, Mesra, Ranchi

Venue

Online

Abstract

In this presentation, I will discuss thermophysical properties in the Gale crater and its surroundings using satellite images from different Mars missions. Thermal Inertia (TI) is one of the significant thermophysical properties for planetary remote sensing applications. Estimating thermal inertia values is crucial in discriminating various surface lithologies and understanding the Martian surface's past and present geological processes. One of the investigated key parameter in this study include Thermal Inertia derived from Thermal Imaging Science Experiment (THEMIS) images. The result suggested seasonal variation in TI values, which depicts an active surface deposition process. Seasonal variation in TI values was influenced by dust; hence, Atmospheric Optical Depth (AOD) was retrieved using HRSC images; the result suggested that the predicted pressure scale height was equal to the scale heights derived for HRSC Nadir channel; also, one region consisted of clouds which added an extra AOD. Further, the influence of AOD on TI and particle size was investigated to understand the phenomenon responsible for dust deposition and lifting. In my proposed research work, I plan to investigate seasonal variations in atmospheric optical depth. These variations in the optical depth observed in images taken at different times can reflect the spatial distribution of optical depth. Understanding the spatial distribution and variation of atmospheric optical depth is necessary for the scientific exploration of the Martian lander or rover and its payload.

Implications from Galactic Archaeology to Exoplanets

Date

2023-07-13

Speaker

Diogo Souto

Venue

Online

Abstract

M-dwarf stars, comprising approximately 70% of all stars in the Milky Way, are the most abundant type of star. However, they remain relatively understudied when it comes to their chemical abundances. This knowledge gap primarily arises from the complexity of their optical spectra, which are heavily influenced by strong molecular bands like TiO and VO. By leveraging near-infrared high-resolution spectra, we have been able to precisely determine stellar parameters and the abundances of up to fourteen elements in these stars. Given the increasing number of Earth-sized exoplanets discovered orbiting M dwarfs, there is a growing interest in characterizing these stellar objects. In this talk, we will explore how studying stellar abundances in M dwarfs can significantly enhance our understanding of Galactic archaeology to exoplanets.

Exploring Exoplanet Atmospheres: Impact of Atmospheric Metallicity on Composition and Observability

Date

2023-07-07

Speaker

Mr. Vikas Soni

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

In the last 25 years, the number of confirmed exoplanets has risen significantly (more than 5000), from terrestrial earth-like planets to the massive gas giant Jupiter-like planet. In the current JWST era, the atmospheric characterization of these exoplanets has become the central theme in studying extrasolar planets. The atmospheric parameters and composition may provide information about planets' bulk elemental compositions, formation, and evolutionary histories. Molecules such as CO, CO2, CH4, H2O, NH3, and HCN, which are the building blocks for more complex organic molecules and significant reservoirs of elemental C, O, and N, have already been detected in exoplanet atmospheres. The abundances of these molecules are probed for the pressure level, where disequilibrium processes can dominate. Atmospheric metallicity is a crucial parameter that controls the total elemental abundance and, thereby, the atmospheric composition. In this seminar, I will discuss how the atmospheric composition of these exoplanets is affected by the atmospheric metallicity in the presence of the vertical mixing, along with a brief introduction of the methodology (1D photochemistry-transport model and quenching approximation) that I have used. I will also show the importance of this study in predicting the observability of chemical species and implementing the result in the atmospheric retrieval method, a common technique for retrieving atmospheric parameters.

Dust, Atmosphere, and Plasma Environment of the Moon and Small Bodies

Date

2023-06-30

Speaker

Mr. Trinesh Sana

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The 4th Dust, Atmosphere, and Plasma Environment of the Moon and Small Bodies (DAP-2023) workshop is hosted by the SSERVI-IMPACT team at the University of Colorado, CO, USA. The workshop agenda included discussions on the current understanding of lunar and small-body surface environments, sharing results from past and ongoing missions, and addressing challenges and solutions for future dusty missions. I am going to present a brief overview of the lectures attended and activities undertaken at the workshop.

The role of outburst floods in Earth and Planetary Evolution

Date

2023-06-16

Speaker

Dr S Vijayan

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Mariner 9 orbiter in 1972 discovered the first channel on Mars, which opened a new research area on how liquid water carved outflow channels. Further, different Mars orbiters provided comprehensive and numerous evidence for widespread, larger channels on Mars. Thus, a new era of comparative planetology emerged between Mars and Earth. On Earth, one of the major flooding events is the Missoula Floods and the Channeled Scabland, which act as a mega flood testing ground for studies that are comparable to Mars. The highly eroded Columbia river basalt bedrock preserved outburst floods produced features like huge cataract complexes, eroded canyons, large streamlined landforms, mega ripples, and immense stratified deposits. Study of the geomorphology and hydrology of outburst floods has, in turn, generated hypotheses regarding the role such floods play in driving climate change and a reater recognition of the geo-hazards associated with outburst flooding. However, the studies on Martian outflow channels revealed that the size, water quantity and the glacial landform are comparatively larger than that of the Earth. The Channeled Scabland formed by cataclysmic erosion and deposition from Pleistocene mega flooding still preserved the paleoflood indicators, which provide crucial clues to understand the magnitudes and frequency of flooding on Earth and Mars.

Introduction to Evershed and Inverse Evershed flows

Date

2023-06-13

Speaker

Mr. Sandeep Dubey

Venue

USO Seminar Hall

Abstract

The Evershed flow is an outflow of plasma in the penumbra of a sunspot, first observed in 1909 by John Evershed at the Kodaikanal Solar Observatory, India. The Evershed effect is observed mainly in photospheric lines. The chromospheric lines such as H-alpha,CaII 8542 present an opposite picture in which an inflow of plasma is observed at chromospheric heights in the solar atmosphere. The inflow of plasma at chromospheric height, known as Inverse evershed flow, is present mainly outside the penumbral region of sunspots. In this talk, I shall introduce the flows with a brief discussion on observations dealing with different physical properties of the flows and models providing a possible mathematical structuring to the flows. I shall also discuss the aspects of these flows that we are working on at present.

Unraveling Mars' Magmatic Past: Insights from Martian Shergottites

Date

2023-06-09

Speaker

Ms. Varsha M Nair

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The formation and evolution of the Martian surface, as well as the fate of its various volcanic regions, are revealed through the chemistry of Martian meteorites and the mineralogy of the crust. The composition, and consequently the evolution of the Martian crust and mantle have been elucidated through SNC (Shergottite-Nakhlite-Chassignite) meteorites. These meteorites serve as the igneous counterparts of rocks originating from Mars and have been brought to the surface through volcanism, offering a glimpse into the interior of the red planet. Martian meteorites, which carry different textures, mineralogy, trace element and isotopic patterns, provide an understanding of the igneous emplacement history of Martian magma and the heterogeneity of mantle reservoirs, thus revealing a complex history of Martian magmatic evolution. A texturally distinct variety of Shergottite is Poikilitic shergottite. This unique samples allow us to investigate how they formed from deep crustal chambers to late-stage evolution in the upper crust of Mars. In this talk, I will address the current understanding of the Martian mantle and its evolution through different meteorites, and specifically explore how poikilitic shergottites can provide further insights into the magmatic history of Mars.

Understanding crustal evolution of terrestrial planets through granitisation

Date

2023-05-22

Speaker

Riya Debacharya Dutta, (MLSU, Udaipur)

Venue

Online

Abstract

To study the crustal evolution and composition of the terrestrial planets, a combination of global spectral imaging, optical imaging, gravity measurements, laser altimetry (remote sensing), in situ investigations, and laboratory analyses of returned samples are desired. Since there is a different level of planetary exploration for each of the terrestrial planets, our knowledge varies strongly among the planets with Mars and the Moon being the most studied bodies so far. For this study, understanding the geology of planet Earth should be very important as it reserves all the in situ evidences of terrestrial planetary evolution. It requires a much more comprehensive picture of the granitoid as it is a major sustainable component of earth’s continental crust. That can be achieved by studying them in regional way and it is necessary since granite result from both plate tectonic process and several magmatic processes (like liquid immiscibility, fractional crystallization, differentiation, partial melting as suggested from several experimental studies and petrological evidences in silicate systems from earth and other terrestrial bodies especially Lunar and Martian rocks) that can produce both new crust and recycle the older crust. In this research proposal, we consider a well-known Precambrian granitoid province as earth analogue to correlate the other granitic and felsic volcanism of inner terrestrial planets and thereby try to understand the role of granite for terrestrial crustal evolution.

Highlights of the sessions from the 54th Lunar and Planetary Science Conference (LPSC)

Date

2023-05-12

Speaker

1. Deepali Singh / 2. Yash Srivastava

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Probing the Solar Corona and Solar Wind Using Ground and Space-based Facilities

Date

2023-05-09

Speaker

Dr. K. Sasikumar Raja

Venue

USO Seminar Hall

Abstract

Ground-based, low-cost low-frequency radio telescopes provide valuable insights into solar transient emissions such as solar flares and coronal mass ejections, and their association with solar radio bursts. Even after decades of intense research on solar radio bursts, we do not thoroughly understand their origin, emission mechanisms, polarisation properties, associated magnetic fields, white light counterparts, association with space weather, and many more. In this presentation, I will discuss the results derived using the observations from various facilities of the Gauribidanur radio observatory, space-based wind/waves, etc. Furthermore, I will discuss solar wind density turbulence and heating rates derived using the Crab Nebula occultation technique. I will also present the way the amplitude of solar wind turbulence, density modulation indices, and proton heating rates vary with the heliocentric distance and solar cycle. Apart from these scientific investigations, I will summarise my contributions to radio instrumentation and the Visible Emission Line Coronagraph (VELC) project. VELC is the internally occulted coronagraph onboard the Aditya-L1 mission, the first Indian mission to explore the Sun and solar corona.

On the chromospheric jets and the associated flows in the solar atmosphere

Date

2023-05-04

Speaker

Mr. Ravi Chaurasiya

Venue

USO Seminar Hall

Abstract

Chromosphere forms one of the layers of the solar atmosphere sandwiched between the photosphere and the highly structured corona. It is highly complex and dynamic in nature, largely dominated by local magnetic field configuration, associated with spicules, jets, mottles, fibrils, etc. It is believed that they carry mass from the lower atmosphere to the higher atmosphere and are generated due to the leakage of p-mode oscillations or magnetic reconnection. In this seminar, I will talk about jet like structures, particularly spicules observed in the chromosphere, their generation mechanism, and the associated flows as they evolve through the solar atmosphere, using the observations from SST, MAST, IRIS, and SDO/AIA.

Shocked meteorites and its minerals: Impact-induced thermo-chemical evolution of asteroids and future planetary exploration

Date

2023-04-28

Speaker

Kishan Tiwari, IIT, Kharagpur

Venue

Online

Abstract

The study of high pressure mineral polymorphs in shocked ordinary chondrites is key to comprehend its formation mechanisms, chemical compositions, and crystal structures in order to understand the dynamics of planetary interiors and the hypervelocity impact during the evolution of the early solar system. A comprehensive and interdisciplinary approach is always beneficial and utilizes the advanced analytical techniques to identify the shocked chondrite samples containing shock-melt veins and melt pockets. This further helps to decode the evidence of multiple impact events, further characterize the criteria to demarcate their specific characteristics in the form of textural imprints, and coalescing phases of contrasting magnitudes. This study will also investigate the origin of high-pressure phases, reconstruct the pressure-temperature-time path experienced, and evaluate the implications of high-pressure phases utilizing ultra-high-resolution electron microscopy. The results can also be used in future planetary missions to constrain fine-grained mineralogy adjacent to impact crater at close vicinity of the lander and rover on any planetary surface. The future research of high-pressure minerals also plays important roles to elucidate how the hypervelocity impacts of extraterrestrial materials affect Earth’s environments. In this talk, I will discuss the new results recently published in GRL, PNAS and JGR-Planets and the possible future scope.

Magnetic coupling of sunspot umbral atmosphere

Date

2023-04-17

Speaker

Ms. Ananya Rawat

Venue

USO Seminar Hall

Abstract

Sunspots host various oscillations and wave phenomena like umbral flashes, umbral oscillation, running penumbral waves, and coronal waves. All the fan loops rooted in the sunspot umbra constantly show a 3-min period propagating slow magnetoacoustic waves in the corona. However, their origin in the lower atmosphere is still unclear. In this work, we studied these oscillations in detail along the clean fan loop system rooted in active region AR12553 for a 4-hour duration on June 16, 2016 observed by Interface Region Imaging Spectrograph (IRIS) and Solar Dynamics Observatory (SDO). We traced the footpoints of several fan loops at different atmospheric heights from the corona to the photosphere. We found presence of 3-min oscillations in the footpoints of all the loops at all the atmospheric heights. We traced the origin of these waves by utilising their amplitude modulation characteristics with time while propagating in the solar atmosphere. We found several amplitude modulation periods, such as 12 min, 22 min, and 35 min of these 3-min oscillations at all heights. Based on our findings, we interpret that 3-min slow magnetoacoustic waves propagating in the coronal fan loops are driven by 3-min oscillations observed at the photospheric footpoints of these fan loops in the umbral region. Results provide clear evidence of magnetic coupling of the solar atmosphere through the propagation of 3-min waves along the fan loops at different atmospheric heights.

Exploring Lunar Geochemistry Beyond Procellarum KREEP Terrain: Insights from Basaltic and Brecciated Meteorites

Date

2023-03-31

Speaker

Yash Srivastava

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The geochemical evolution of the Moon is primarily understood in term of returned samples from the Apollo, Luna and Chang’E 5 missions. Although samples returned from the Moon provide valuable insight into its evolution, they are not a comprehensive representation because they are primarily collected from regions with high concentrations of incompatible elements, known as Procellarum KREEP terrain (PKT). The returned samples are dominantly mare basalts, anorthosite, and pyroclastic glasses which provide insight to interior processes such as volcanisms. Alternatively, breccias, which formed on the lunar surface offer us to understand exterior process such as meteoritic bombardment on the Moon. This talk will discuss the significance of the two different varieties of lunar meteorites in understanding the Moon's geochemical evolution. First, I will explain the petrogenesis of some KREEP-free lunar basalt meteorites which provides us insight to lunar mantle and its thermo-chemical evolution. Later, I will discuss about the lithological and compositional diversity of the lunar crust using the lunar breccia meteorites and the signatures of preserved external and internal processes in these samples.

Rapidity - dependent Jet vetoes at NNLL' + NNLO using SCET

Date

2023-03-30

Speaker

Dr. Shireen Gangal

Venue

Room no: 469 (Main Campus)

Abstract

In this talk, I present resummed predictions for Higgs production via gluon fusion, and Drell-Yan production, in the framework of Soft Collinear effective theory (SCET). I introduce rapidity-dependent jet veto observables which provide a tight veto at central rapidities, gradually transitioning to a loose veto at forward rapidities. They divide the phase space into exclusive jet bins in a different way to the traditional jet veto observable pTjet. Using these rapidity-dependent jet vetoes, I present results for the 0-jet gluon-fusion Higgs cross section, and preliminary predictions for Drell-Yan at NLL’ + NLO and NNLL’ + NNLO. A significant reduction in perturbative uncertainty is observed going from NLL'+ NLO to NNLL'+ NNLO.

DEMYSTIFYING LEADERSHIP<img src='/prl-eng/images/red.gif'>

Date

2023-03-29

Speaker

Prof. Asha Kaul

Venue

K R Ramanathan Auditorium, PRL Main Campus, Ahmedabad

Abstract

The concept of ‘leader’, ‘leader communication’ and ‘leadership’ has gained momentum over the years. Though there is a plethora of research on the topic of ‘leadership’ there is no one definition to which all practitioners and academics subscribe. There are differing outcome-based perceptions and then there are process focused assessments –the debate is ongoing and inconclusive. The question, - ‘Where then can we draw our leadership lessons from?’, becomes all the more pertinent in this environment of uncertainty. I propose that knowledge on the topic can be derived from one of the oldest and longest epics of India – Mahabharata. Written in the third century BC in the form of Itihaas (history), it presents narratives of leader stratagems and propels the reader to draw lessons for almost all fields of operation. All characters in Mahabharata have a narrative which advocates strategies for people in leadership positions or which may be termed as the Leadership Act on how mindsets are created, plans are communicated and executed, the role of love, passion, hatred and envy and the consequences of the same. The legitimacy of the leadership act – embedded in the moral as well as pragmatic – leads us to the notion of Principled Pragmatism, that is, ethical principles, character and relationships. And what better text than Mahabharata is there which can teach us through the narratives principles of leadership – what should be followed and what should be avoided.

Study of Reconnection Dynamics and Plasma Relaxation in MHD simulation of a Solar Flare

Date

2023-03-27

Speaker

Mr. Satyam Agarwal

Venue

USO Seminar Hall

Abstract

During solar transients such as solar flares and jets, the stored magnetic energy is released explosively in the form of heat and acceleration of the charged particles. The underlying cause of these transients, i.e. the magnetic reconnection process has long been associated with the self-organization or relaxation of magnetized plasmas. In this regard, Taylor's theory (1974) has been investigated quite extensively during the past few decades but a thorough understanding of the relaxation process is still a long way off. While previous studies have focused mostly on analytical magnetic fields, we adopt a novel approach in this study and utilize the data-constrained magnetohydrodynamics (MHD) simulation of an observed solar flare as the governing framework to explore relaxation and to test the predictions of Taylor's theory. The selected active region NOAA 12253 hosts a GOES M1.3 class flare. The investigation of extrapolated coronal magnetic field in conjunction with spatiotemporal evolution of the flare reveals a hyperbolic flux tube (HFT), overlying the observed brightenings. Further, MHD simulation is carried out with the EULAG-MHD numerical model to explore reconnection dynamics. Three distinct sub-volumes are chosen and are subjected to analysis of magnetic field line dynamics along with time evolution of various physically relevant quantities such as magnetic energy, current density, twist, and gradient in magnetic field. In my talk, I will be presenting the theory of self-organization, helicity, MHD relaxation, and Taylor’s relaxation followed by results, summary, and discussion.

Spontaneous generation and annihilation of three-dimensional magnetic nulls

Date

2023-03-23

Speaker

Mr. Yogesh Maurya

Venue

USO Seminar Hall

Abstract

Three dimensional (3D) magnetic nulls are the location where magnetic field is zero. They are preferential sites for magnetic reconnection and triggering solar coronal transients, for example: solar flares, coronal mass ejections and coronal jets. Such 3D nulls are abundant in solar atmosphere but mechanism of their generation or the reason of their abundance is yet a puzzle. Toward solving this puzzle, the dynamics of an analytical initial magnetic field having an isolated current-free 3D null is numerically simulated with initially prescribed flow. The flow facilitates reconnections, which lead to the generation of primary null pairs in a way that preserves the topological degree. The formation process of these null pairs is novel and different from the standard pitchfork bifurcation. In standard pitchfork bifurcation the additional nulls get created within the current layer developed at the central null. Contrarily, here we found creation of null pairs away from the central null, which we hypothesize is due to the interaction of the imposed flow and the reconnection outflow from the central current layer. Intriguingly, further evolution spontaneously generates new null pairs, which have a novelty by itself. As theorized, these spontaneously generated null pairs also preserve the net topological degree—adding credibility to the simulation. The simulation also shows null pair annihilation. In the talk, I will discuss the results in detail together with the identified mechanism responsible for the generation and annihilation of the nulls.

Some experiments of relevance for PAHs in the Solar System

Date

2023-03-17

Speaker

Dr. Vinitha M V, Postdoctoral researcher, PIIM Laboratory, Aix-Marseille University, Marseille, France

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Polycyclic aromatic hydrocarbons (PAHs) are one of the dominant organic compounds present in the extraterrestrial rocks formed in the early solar system. These molecular species have already been detected in many other astronomical environments. Much laboratory astrophysics research in the past few decades has been dedicated to investigating the molecular properties of PAHs. It is widely accepted that these molecules become highly reactive after interacting with various astronomical radiations and form nitrogen and oxygen containing aromatic organic molecules [1]. Some of them are already detected in carbonaceous chondrite (CC) meteorites. Apart from this perspective, meteoritic PAHs are nowadays seen as a possible tracer of various physical conditions under which these primitive rocks are formed or evolved. GC-MS is an established technique for high-level molecular analysis on meteoritic PAHs. But this technique requires sample to be available in milligram quantities and never enables the determination of spatial distribution of PAHs across a given sample. In this context, several other mass spectrometric techniques are emerging in the field. One of them is microprobe two stage laser desorption laser ionization mass spectrometry. One such instrument called AROMA is available in IRAP, Toulouse, France. This instrument is specially designed to perform high level molecular analysis on meteoritic PAHs. For instance, very recently this instrument is coupled with a third laser to enable direct detection of m/z 202.02 PAH isomers (one of the most abundant PAH in different carbonaceous samples) by visible multiphoton dissociation. The technique in detail and the results on multiple CCs will be discussed in the talk. Moreover, another unique mass spectrometric technique developed at AMP, IIST, Thiruvananthapuram to investigate various astronomically relevant dissociation channels of PAHs will also be discussed in the seminar.

Design, Development and Performance Modelling of WALOP Polarimeters for PASIPHAE Survey

Date

2023-03-16

Speaker

Dr. Siddharth Maharana

Venue

Thaltej Seminar room (113)

Abstract

PASIPHAE survey aims to create the first large sky magnetic field and dust cloud tomographic map of the Galactic polar regions using stellar polarimetry and GAIA stellar distances. Two WALOP (Wide-Area Linear Optical Polarimeter) instruments, to be mounted on 1 m class telescopes in South Africa and Greece are currently under development to work as survey instruments for the PASIPHAE program for creating the stellar polarization catalogue. Scheduled for commissioning in 2023, the WALOPs are being designed to operate with the combined capabilities of one-shot four camera linear polarimetry, low polarization systematic (polarimetric accuracy of 0.1%) and a large field of view of 30×30 arcminutes, which in combination will make these unique astronomical instruments. Operating in the SDSS-r broadband and narrowband filters between 500-700 nm, for each exposure, four images of the full field corresponding to polarization angles of 0, 45, 90 and 135 deg will be generated and carrying out differential photometry on these images will yield the linear Stokes parameters. We have developed a complete design and calibration strategy for WALOPs to achieve its technical goals. In this talk, I will present an overview of the instrument design, development, performance modelling and calibration routine for the instruments and their current status.

Reviving the sterile neutrino dark matter with neutrino secret self-interactions

Date

2023-03-16

Speaker

Dr. Manibrata Sen

Venue

Online ---> https://bluejeans.com/512808345/1781

Abstract

Sterile neutrinos with masses around a few keV have been postulated to be viable dark matter candidates. This is, however, mostly in tension with various astrophysical observations, the most stringent being the X-ray bounds. In this talk, I would like to present a testable sterile neutrino dark matter production mechanism in the early Universe. The idea is to introduce a light scalar particle that mediates self-interactions among the Standard Model neutrinos. Such interactions enable the sterile neutrinos to be more efficiently produced in the early universe, thus alleviating the tensions and allowing the sterile neutrinos to be perfectly lucrative dark matter candidates. Such secret self-interactions can be tested in future neutrino experiments like DUNE. Apart from laboratory bounds, I will also discuss how these interactions can lead to exciting signatures in the early Universe as well as core-collapse supernovae.

Martian meteorite and hydrogeology on Mars

Date

2023-03-10

Speaker

Aditya Das

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

In contrast to the Noachian era, the Amazonian era is drier, so the extent of the water-rock interaction on Mars during the Amazonian is limited to the secondary minerals (clays) found in the Nakhlite group of Martian meteorites. The Nakhlite group of meteorites are clinopyroxene-rich igneous cumulate rocks that are thought to be formed from thick lava flow or shallow sill. In this study, the alteration products in the Nakhlites will be analyzed to understand the reaction between the primary crust with liquid water in the recent Amazonian era. Thus, this study will help us to understand many important aspects, like the possible pathway for fluid circulation, the relative lifetime of formation of secondary minerals, and the nature of the reacting fluid/s bringing about such alteration.

Bosonization, Chiral L¨uttinger Liquid, Spin chain and Quantum Hall

Date

2023-03-02

Speaker

Dr. Ankur Das

Venue

Room no: 469 (Main Campus)

Abstract

Bosonization is a general technique/formalism that helps us in taking 1D interacting fermion problem and turning them into effective non-interacting boson problem. I will talk in detail about the formalism, the assumptions, and the basics. I will go through also the mapping between operators and Hamiltonian in these two languages. I will discuss how they connect to the quantum Hall edge mode (Chiral L¨uttinger Liquid). Next, I will discuss the same for a simple spin chain model (XXZ spin chain) and how that can be mapped to L¨uttingerLiquid and neutral modes (spin wave). I will then discuss how interaction can play a role in detecting these neutral modes that we have discussed in our work [PRB 105, 165154 (2022)]

The Solar System's Great Divide

Date

2023-03-01

Speaker

Dr. Ramon Brasser, Senior planetary scientist, Research Centre for Astronomy and Earth Sciences, Budapest, Hungary

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

The Solar System is divided into two distinct regions: the inner and the outer part. The inner solar system is populated by small, rocky planets while the outer solar system's inhabitants primarily consist of the four giant planets.How did this architecture come about? How did the rocky and giant planets form, on what timescale, and from what materials? My research focuses on using numerical N-body simulations and isotopic anomalies and chronology from extraterrestrial samples to piece together the dynamical history of the solar system. In this presentation I give an overview of my work, what we know, what we don't know, and briefly mention a pathway for future research.

Topological Semimetals beyond regular

Date

2023-03-01

Speaker

Dr. Ankur Das

Venue

Room no: 469 (Main Campus)

Abstract

Topological semimetals in three dimensions occur in mainly two variants, with the bands touching at point nodes (Weyl or Dirac semimetals) or touching at nodal lines in the Brillouin zone. However, there are new semimetals that challenge our notion, namely Nexus. Their existence needs lattice symmetry their classification needs an extra understanding of the system than usual. I will discuss how to understand the topology of Nexus Semimetals. On the other side while Weyl/Dirac semimetals can occur with internal symmetries only (such as time-reversal, charge conjugation, and possibly a product of the two, called chiral/sublattice symmetry), nodal line semimetals have been believed to require more symmetry, such as SU(2) spin rotation or crystalline symmetries. Though there has been discussion about possible topological classification of nodal line, how does in a generic the symmetry-constrained model they appear is not understood well. We show that chiral symmetry classes that are topologically nontrivial in three dimensions (namely class AIII, CII, DIII, and CI) always have a stable gapless phase, which is a topological nodal line semimetal even for the minimal model. We emphasize that no lattice or spin rotation symmetries are required for their robustness.

Su-Schrieffer-Hegger model with a non-orientable bulk: Union of topology and flat bands in one dimension

Date

2023-02-28

Speaker

Bharathiganesh D

Venue

Room no: 469 (Main Campus)

Abstract

The Su-Schrieffer-Hegger model is the most simple but complete model of topological band insulators exhibiting features like bulk boundary correspondence. We investigate the possibility of the bulk in this model being a non-orientable manifold and consequences thereof. We find that in this case the topology of the SSH model is preserved along with the appearance of a doubly degenerate flat band at the Fermi level. We also find that there are states localised in the bulk along with the non-trivial edge modes in a finite chain. We will begin the talk with an introduction to band topology through the SSH model and continue to the case with non-orientable bulk.

Modelling of Cometary Atmosphere

Date

2023-02-24

Speaker

Kinsuk Acharyya

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Comets are made up of the leftover materials that formed our solar system and are the least altered objects surviving the protoplanetary disks. They are the building block for the cores of outer planets and transport water and organics throughout the planetary system. Also, it played a crucial role in the habitability of terrestrial planets. Thus the study of comets and their composition is of paramount importance. Most information about comets comes from studying their atmosphere or coma, formed during perihelion passage. Active chemistry occurs in the coma, and the energy released due to chemical reactions is non-uniformly distributed amongst the volatile species in the coma, resulting in different temperatures. Numerical simulation can be employed to understand the formation of cometary volatiles in the cometary coma. We developed a multifluid numerical model to study how the chemistry and dynamics of the coma of a comet change for varying abundances of the major volatiles, which will be discussed in the presentation. The model uses the fluid conservation equations for number density, mass, momentum and energy. It considers neutrals, ions and electrons as three separate fluids. Besides chemical reactions, we have also considered the energy exchange between the three fluids due to elastic and inelastic collisions. The fluid conservation equations can be written as first-order differential equations in species number density, velocity and temperature. Numerical integration of these equations gives the temperature and velocity profiles of the coma for varying cometocentric distances. In the presentation, I will discuss various facets of the modelling of the cometary atmosphere and our study of the coma of the first interstellar comet 2I/Borisov and a few other comets, emphasising the formation of organic species.

Near infrared background with the 1.2 m telescope at Mount Abu

Date

2023-02-23

Speaker

Ms. Prachi V. Prajapati (Scientist/Engineer SD, A&A division PRL)

Venue

Room no. 113/114 Thaltej

Abstract

Study of the background in astronomical observations plays a crucial role in understanding the characteristics of background noise. In this seminar, I will be discussing the estimation and analysis of the Near Infrared (NIR) background for the astronomical site at Mount Abu. Data obtained from the NIR observations of various sources using the Near Infrared Camera/Spectrograph (NICS) on the 1.2 m telescope are used in this study to derive the NIR background estimates. We notice seasonal variations in these values, with the summer months showing slightly brighter background compared to the winter. A comparison of synthetic atmospheric transmission at Mount Abu with other Indian observatories at various altitudes will also be presented. We identify the plausible contributors to the NIR background in our observations and discuss the potential ones that can contribute to the noticed seasonal variations. Overall, we find that the NIR background does not show any systematic variation over the period of the observations from 2010 to 2019.

Out-of-time-order correlators of nonlocal block-spin and random observables in integrable and nonintegrable spin chains

Date

2023-02-23

Speaker

Mr. Rohit Kumar Shukla

Venue

Online ---> https://bluejeans.com/299910903/4490

Abstract

Out-of-time-order correlators (OTOC) in the Ising Floquet system, that can be both integrable and nonintegrable is studied. Instead of localized spin observables, we study contiguous symmetric blocks of spins or random operators localized on these blocks as observables. We find only power- law growth of OTOC in both integrable and nonintegrable regimes. In the non-integrable regime,beyond the scrambling time, there is an exponential saturation of the OTOC to values consistent with random matrix theory. This motivates the use of “pre-scrambled” random block operators as observables. A pure exponential saturation of OTOC in both integrable and nonintegrable systems is observed, without a scrambling phase. Averaging over random observables from the Gaussian unitary ensemble, the OTOC is found to be exactly same as the operator entanglement entropy, whose exponential saturation has been observed in previous studies of such spin-chains.

Lunar Surface Thermophysical Behaviour - Complications and Implications

Date

2023-02-17

Speaker

Durga Prasad Karanam

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Jupiter’s saltwater ocean world Europa: a template for life beyond Earth and alkali-rich exomoons beyond the solar system

Date

2023-02-10

Speaker

Dr. Apurva V. Oza (Chief Scientist Postdoc, JPL (USA))

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Jupiter’s innermost Galilean satellite Io is the most volcanic body in the solar system, orbiting at ~6 Jovian radii. The subsequent Europa at ~9.6 Jovian radii also experiences tremendous tidal heating — melting its ice and possibly cryovolcanically venting saltwater into its exosphere. Europa’s sodium & potassium (Na/K) exosphere is sputtered from its brine-rich surface forming a patchy sodium torus directly linked to its outgassing and possibly its oceanic interior, conducive to life. With the aid of evaporative transmission spectroscopy, neutral sodium and potassium are regularly observed at transiting gas giant exoplanets. Here we show how dozens of exomoon candidates, >> 10,000x more powerful in mass flux than Io and Europa, may be actively populating the exospheres of exoplanets. Especially compelling exomoon candidates showcase spectral disappearances of Na&K at select systems, meriting follow-up by high-resolution and space-based spectrographs onboard HST/JWST.

Accretion around black holes: The geometry and spectra

Date

2023-02-09

Speaker

Narendranath Layek

Venue

Room no. 113/114 Thaltej

Abstract

The most energetic phenomena of our universe are generally powered by the process of accretion onto compact objects. This process releases energy through radiation. When accreting material has angular momentum, it forms a disc-like structure around the central object at the equatorial plane is called an accretion disc. There are various types of disc mechanisms present in the literature. Between them, the Standard disc, proposed by Shakura and Sunyaev in 1973, is the most preferred disc model, which is used widely to explain the disc accretion around any compact object. This model predicts disc properties like spectral energy distribution and luminosity and has been validated by observations of various astrophysical systems. In this talk, I'll give a brief overview of various accretion processes, including disc accretion and the associated radiation mechanisms.

Remote sensing studies of planetary regolith surfaces: Topographic mapping, reflectance spectroscopy, photometry, polarimetry, thermal modelling, machine learning - and linking them all up

Date

2023-02-08

Speaker

Prof. Christian Wöhler (Image Analysis Group, Technical University of Dortmund, Dortmund, Germany)

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

This talk provides an overview of a variety of remote sensing methods developed at the Image Analysis Group of TU Dortmund University, operating in the visible, near-infrared and thermal infrared wavelength domains. Applications to the Moon, Mars, Mercury and an atmosphereless exoplanet demonstrate the wealth of information obtainable by such techniques once they are mutually linked up. Particular emphasis is dedicated to (i) the topographic and thermal correction of reflectance spectra from planetary regolith surfaces, (ii) the resulting time-of-day-dependent detection of surficial water/hydroxyl on the Moon, (iii) the estimation of elemental and mineral abundances based on hyperspectral imaging, (iv) the determination of physical regolith properties such as small-scale roughness, porosity and grain size, and (v) automatic geomorphological mapping.

TPC #7: Measuring Entanglement in Electronic Interferometers

Date

2023-02-07

Speaker

Prof. Yuval Gefen

Venue

K. R. Ramanathan Auditorium, PRL main campus

Abstract

This talk will rely on two fundamental themes of quantum physics: the statistics of identical particles, and entanglement. The former was thrust into the limelight, given the theoretical and experimental search for anyonic (fractional) statistics. The latter is a pillar of quantum mechanics: quantum entanglement prevents us from obtaining a full independent knowledge of a subsystem. Can one, theoretically and experimentally, focus on and isolate statistics-induced entanglement? Here I will address this question, addressing the case of fermions.

Dynamical Generation of Dark Matter and Electroweak Scales

Date

2023-02-01

Speaker

Dr. Anish Ghoshal

Venue

Online ---> https://bluejeans.com/482088260/6256

Abstract

The Standard Model (SM) of particle physics suffers from the hierarchy problem which can be ameliorated if all the scales that we observe in nature are considered not to be fundamental but generated dynamically in nature. As examples, we will discuss freeze-out and freeze-in production of vector dark matter (DM) in a classically scale invariant theory, where the Standard Model (SM) is augmented with an extended gauge symmetries that are spontaneously broken due to the non-zero vacuum expectation value (VEV) of a scalar. Generating the SM Higgs mass at 1-loop level, it leaves only two parameters in the dark sector, namely, the DM mass mX and the gauge coupling gX as independent. For freeze-in, which require very feeble coupling to satisfy the relic, the scenario is testable in several light dark sector searches (e.g., in DUNE and in FASER-II) as well as direct detection probes in a complementary manner courtesy to the underlying scale invariance of the theory. We will show scenarios for neutrino-portal, axion-portal, Zprime-portal and HIggs-portal freeze in DM. In the second part of the talk we will briefly show how gravitational waves can be used to test freeze-in DM and complemented with laboratory signals.

From hot Jupiters to super-Earths: Exoplanets and beyond

Date

2023-01-31

Speaker

Dr. Priyanka Chaturvedi

Venue

Thaltej Seminar room (113)

Abstract

The search for planets beyond our solar system is one of the biggest scientific quests at present. The first exoplanet detection by the radial velocity (RV) method nearly three decades back was awarded the Nobel prize in Physics. Since then, the number of exoplanets found has increased exponentially with nearly 5000 exoplanet detections till date. We have learnt that diverse planetary systems form with orbits, densities, and planetary atmospheres that are very different from the planets in our solar system. In my talk, I will discuss planet demographics across the stellar spectral range focusing on large planets around the solar-type stars and smaller planets around the late spectral type stars. Despite the advent of large telescopes and precise spectrographs, the detection of smaller planets is largely limited by the intrinsic stellar jitter. I will talk about the ways that we devise to disentangle this stellar jitter from the planet signature. I will finally highlight the role of small to medium-size telescopes for exoplanet characterization in the era of current and future space missions like TESS and PLATO.

On the origin of a kiloparsec size superbubble in the JWST images of the "phantom galaxy" NGC628

Date

2023-01-23

Speaker

Prof. Yalia Divakara Mayya

Venue

Thaltej Seminar room (113)

Abstract

NGC628 is the first nearby galaxy for which JWST data became available to the public. The most striking characteristic of the publicly released MIRI image is the presence of a large number of "holes" in an otherwise bright mid-infrared (MIR) emitting disk. This porous structure has given it a popular nickname "phantom galaxy". The "holes" are most often expanding bubbles or superbubbles that are created by the mechanical power output by the massive stars in young star clusters. However, few cases exist where the stellar population that was responsible for the creation of the bubble was unambiguously identified. We here analyze the largest of the bubbles in the JWST/MIRI image of NGC628, measuring 1.3 kpc in diameter to understand the origin of such large bubbles. We combined the JWST NIRCam and MIRI dataset with archival images from the HST, ALMA, VLA and MUSE, to identify the resolved population that might be responsible for the creation of the bubble, and to map the multiphase morphology and kinematics of the gas in the shell surrounding the bubble. The bubble is dominated by the molecular gas and is expanding at 12 km/s velocity. We find conclusive evidence for the presence of a resolved stellar population of ages between 5 to 50 Myr inside the bubble, whose collective mechanical power output is sufficient to explain the presently observed radius, velocity and the shell mass. In the talk, I will discuss the star formation scenario inside the bubble and the conditions that favour the formation of large superbubbles.

An extremely enhanced ionization in the E region ionosphere of Mars: Modelling and observations

Date

2023-01-23

Speaker

Siddhi Shah

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Mars Advanced Radar for Subsurface and Ionosphere Sounding (MARSIS) experiment onboard Mars Express (MEX) observed a few events of extremely strong ionizations when the E-peak electron density enhanced significantly at altitude ~90-100 km. These observations were carried out in the mini-magnetosphere of Mars between latitude 54oS to 55oS and longitude 177oE to 182oE. Observation of such strong density at this low altitude demands a source mechanism. We report an unusual event on 2 June 2012 of MARSIS onboard MEX during orbit # 10723 at Ls 119o, when the E-peak electron density ~1.7 x 105 cm-3 enhanced significantly at altitude ~ 100 km. This peak density is higher by about an order of magnitude from the E peak density observed by Radio Occultation Science Experiment (ROSE) onboard Mars Atmospheric and Volatile Evolution (MAVEN). We have modeled observed electron density profiles using coupled continuity and Analytical Yield Spectrum (AYS) approach. The estimated electron density due to solar EUV/X-ray is matching well with the ROSE observation. The enhanced E-peak density in the MARSIS profile is produced due to high-energy electron impact.

The Phase puzzle of ν = 0 (charge neutrality) Graphene and Beyond

Date

2023-01-19

Speaker

Dr. Ankur Das

Venue

Online ---> https://bluejeans.com/955982537/8037

Abstract

The true ground state of ν = 0 (charge neutrality) monolayer graphene quantum Hall has long been debated. Famously the symmetry of the monolayer graphene at ν = 0 (charge neutrality) was analyzed by J. Alicea and P. A. Fisher (PRB 2006), and canted anti-ferromagnet (CAF) was predicted by I. F. Herbut (PRB 2007). However, the complete picture of the Hamiltonian was missing until the seminal paper by M. Kharitonov (PRB 2012), which predicts a phase transition from a vanilla insulator (CAF) to a topological insulator Ferromagnetic phase (F) as one changes the Zeeman energy keeping the cyclotron energy fixed. This was later confirmed in the experiment by A. F. Young et al. (Nature 2014). Motivated by recent experiments (L. He et al. PRB 2019; Ali Yazdani et al. Science 2022; B. Sacepe et al. Nature 2022), we revisit this phase diagram. We show that, generically, in the regime of interest, there is a region of coexistence between magnetic and bond orders in the phase diagram. We demonstrate this result both in continuum and lattice models and argue that the coexistence phase naturally provides an explanation for unreconciled experimental observations on the quantum Hall effect in graphene. We further extend this idea to the whole phase diagram. This opens up many questions about different possibilities and new ideas, and possible mesoscopic experimental consequences.

Non-monotonic potential structures within lunar photoelectron sheath

Date

2023-01-13

Speaker

Trinesh Sana

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

A dusty photoelectron sheath near the sunlit lunar surface is anticipated under the dynamic interaction between solar irradiation and ambient plasma. Determining the justifiable electric potential structure within the lunar photoelectron sheath has been an active area of interest. Electron distributions measurement of Lunar Prospector (LP) above the dayside lunar surface indirectly implied the existence of a non-monotonic electric potential structure near the lunar surface. I will be discussing the physics behind the non-monotonic potential structure formation using justified solar spectrum, solar wind flux, and adequate photoelectron distribution.

Hard X-ray polarimetry with CZT Imager onboard AstroSat: An overview of the technique and recent scientific findings

Date

2023-01-12

Speaker

Dr. Tanmoy Chattopadhyay

Venue

Thaltej Seminar room (113)

Abstract

CZT Imager onboard AstroSat is primarily a hard X-ray spectroscopic instrument but provides sensitive polarization measurements above 100 keV for bright X-ray sources, e.g. Crab pulsar and the Cygnus X-1 black hole system. With an accumulated 800 ks of observation, CZTI provided till date statistically the most significant polarization measurement for Crab. Phase-resolved polarimetry of the pulsed radiation of Crab was also attempted for the first time in X-rays and the findings provided interesting insights to the emission site of hard X-rays. In the case of Cygnus X-1, the recently dedicated long AstroSat observations show a strong dependence of polarization properties on the spectral state of the source. This is an interesting finding and might be useful in understanding possible disk-jet interplay in black hole systems. Another important characteristic of CZTI is the increasing transparency of the support structure in hard X-rays, which enables it to function as a wide field hard X-ray monitor providing an unique opportunity for GRB detection and polarization measurement. From a sample of a large number of GRBs detected by CZTI in the last 5 years, we attempted polarization measurement for 20 bright GRBs. Time integrated analysis of the prompt emission yields low or no polarization indicating that GRB prompt emission is highly structured leading to possible changes in the polarization angle within a burst which has also been seen independently for some of the bright AstroSat GRBs. A large sample of such polarization measurements in the future is supposed to shed more light into the emission mechanism of GRB prompt emission. In this presentation, I would briefly discuss these recent scientific findings from CZTI. Polarization measurement in hard X-rays for CZT based large area instruments is challenging because of multiple factors, e.g. large background, difficulty in reconstructing the Compton events properly in a single crystal detector plane, systematic effects because of square pixel geometry and the effect of charge sharing. Polarization measurements also critically depend on the accuracy of the mass model of the instrument and the spacecraft particularly for off-axis sources like GRBs. We inspected each of these effects carefully and developed our analysis algorithm over the last few years. I would highlight these challenges and their effects in the context of CZTI polarimetry technique.

Development and characterization of fast low noise X-ray detectors for the next generation astronomical observatories.

Date

2023-01-10

Speaker

Dr. Tanmoy Chattopadhyay

Venue

Thaltej Lecture room (113)

Abstract

The next generation of large X-ray astronomical missions (e.g. the Lynx Great Observatory and AXIS probe class mission concepts) are planned to have an order-of-magnitude larger collecting areas combined with exquisite mirror quality, enabling unprecedented exploration of the faint and high redshift X-ray universe. An essential component of these mission concepts is the development of focal plane instrumentation with fast readout and excellent noise performance - crucial especially for the soft X-ray performance - on the order of single electrons. MIT Lincoln Laboratory (MIT-LL), MIT Kavli Institute (MKI) and Stanford University (SU) have together made substantial improvements in developing next generation X-ray CCDs, and associated readout electronics to support these detectors. We recently characterized a prototype CCD at 4 Megapixel/s (40 times faster than Chandra CCDs) with good noise performance. In parallel, we are also working on a novel Single electron Sensitive readout stage (SiSeRO) for CCDs, and potentially active pixel sensors, which can in principle provide even greater responsivity and better noise performance than contemporary JFET technology. The SiSeRO technology uses a p-MOSFET transistor with a depleted back gate region beneath the transistor channel. The transistor source-drain current is modulated by the transfer of charge into the back gate region. The first SiSeRO prototype devices already achieve a charge to current conversion gain of >700 pA per electron, an equivalent noise charge (ENC) of 4.5 electrons root mean square (RMS), and a full width half maximum (FWHM) of 130 eV at 5.9 keV at a readout speed of 625 Kpixel/s. Importantly, utilizing the benefit that the charge signal remains unaffected by the readout process in these devices, we have also been able to implement Repetitive Non-Destructive Readout (RNDR) on our prototype devices, achieving significantly improved ENC performance. In this talk, I will discuss the working and characterization test results for these new fast, low noise X-ray CCDs and the novel SiSeRO devices.

Geochemical study of Martian meteorites

Date

2023-01-06

Speaker

Varsha M Nair

Venue

Seminar Room # 113/114 (Thaltej Campus)

Abstract

Significant insight into Mars has been gleaned from the ~260 Martian meteorites. In the absence of a sample return mission, meteorites are the only samples available from Mars. However, with addition of new meteorites and ever-growing dataset of surface compositions, new perceptive about the chemical condition and evolution of Mars has been recently understood. The shergottites are the most abundant type of Martian meteorites, accounting for 89% of the total collection by number and 82% by mass. Shergottites are geochemically classified based on their relative enrichment or depletion in incompatible trace elements (ITE), and these ITE compositions are largely inherited from their mantle sources. Shergottites can also be classified into different groups according to their texture, and different textures represent mineral formation and emplacement in the shallow subsurface or perhaps eruption at the surface, which gives an understanding of the igneous emplacement history of Martian magma. As a result, the study of Shergottite samples provides various insights into the Martian interior and the extent of its heterogeneity. In this presentation, I’ll be briefly discussing about different type of Shergottites and how the study on the samples can give insight on the interior of Mars.

A Type I+II seesaw model without Electroweak (EW) hierarchy

Date

2023-01-06

Speaker

Debashis Pachhar

Venue

Room no: 469 (Main Campus)

Abstract

The Standard Model (SM) has passed all the precision tests in the past decades and provides the best description of the Electroweak (EW) and Strong interaction in nature. However there are motivations to tread beyond the SM, one of which is neutrino oscillations which established that neutrinos have small but non-zero mass. The most elegant mechanism to generate such small masses is the seesaw mechanism in which the smallness of neutrino masses is explained by introducing one or more heavy particles at a high scale. Two popular variants of these are the type-I and type-II models which require induction of singlet neutrinos and triplet Higgs fields respectively. Both these models are phenomenologically attractive but they suffer from the EW hierarchy problem. In this talk, I will explore the possibility of addressing this issue in the context of the type I+II seesaw model.

Deciphering the \sim 18 TeV photons from GRB 221009A

Date

2023-01-05

Speaker

Prof. Sarira Sahu

Venue

Room no: 469 (Main Campus)

Abstract

On 9 October, 2022, an extremely powerful gamma-ray burst, GRB 221009A, was detected by several instruments. Despite being obstructed by the Milky Way galaxy, its afterglow outburst outshone all other GRBs seen before. LHAASO detected several thousands very high energy photons extending up to 18 TeV. Detection of such energetic photons are unexpected due to the large opacity of the Universe. It is possible that in the afterglow epoch the intrinsic very high energy photon flux from the source might have increased manifolds, which could compensate the attenuation by pair-production with the extragalactic background light. We propose such a scenario and show that very high energy photons can be observed on the Earth from the interaction of very high energy protons with the seed synchrotron photons in the external forward shock region of the GRB jet.