Tracing the origin of heavy elements through metal-poor stars (Record no. 36103)

MARC details
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fixed length control field 05565 a2200253 4500
003 - CONTROL NUMBER IDENTIFIER
control field IN-BaIIA
005 - DATE AND TIME OF LATEST TRANSACTION
control field 20250825170028.0
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION
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040 ## - CATALOGING SOURCE
Transcribing agency IIA Library
100 ## - MAIN ENTRY--PERSONAL NAME
Personal name Saraf, Pallavi
9 (RLIN) 49249
245 ## - TITLE STATEMENT
Title Tracing the origin of heavy elements through metal-poor stars
Statement of responsibility, etc. Pallavi Saraf
Medium [Thesis]
260 ## - PUBLICATION, DISTRIBUTION, ETC.
Place of publication, distribution, etc. Bangalore
Name of publisher, distributor, etc. Indian Institute of Astrophysics
Date of publication, distribution, etc. 2024
300 ## - PHYSICAL DESCRIPTION
Extent xxiii, 263p.
502 ## - DISSERTATION NOTE
Degree type Doctor of Philosophy
Name of granting institution Pondicherry University, Puducherry
Year degree granted 2024
520 ## - SUMMARY, ETC.
Summary, etc. The hierarchical mass assembly of galaxies and the formation timescales of their substructures are important topics in astrophysics and cosmology. These aspects can be explored in the local universe by studying resolved stars. By analyzing individual stars and stellar populations, one can estimate their ages. Although the color-magnitude diagram of co-evolved stellar populations aids in age determination, dating field stars is more complex. Typically, the iron content (or metallicity) of stars serves as an age indicator. However, metallicity is influenced by the history and rate of star formation. Analyzing multiple chemical elements can provide additional insights. Yet, using elements heavier than iron, particularly those formed by rapid neutron capture, hinges on understanding their astrophysical origins. Identifying these origins remains a significant challenge and a key question in nuclear astrophysics. This thesis investigates chemical compositions of metal-poor stars, aiming to understand their origins and chemical evolution. Halo stars, which are some of the Galaxy’s oldest, offer insights into the astrophysical sites of element production due to their minimal pollution by progenitor stars. Utilizing high-resolution spectroscopic analysis through telescopes such as the 10-m GTC, 8.4-m VLT, 10-m KECK, and 2-m HCT, and supplementing with low-resolution spectra from LAMOST, this study analyzes the detailed abundances of approximately 50 stars. These stars, with metallicities ranging from −3.2 to −1.8, include many classified as very metal-poor and extremely metalpoor, with their chemical compositions examined for the first time. The findings are systematically presented across the thesis. The initial findings of the thesis include a comprehensive abundance analysis of four r-process enhanced (RPE) stars, utilizing the HORuS spectrograph at 10-m GTC. These stars are in the metallicity range of −2.3 to −1.9. The high SNR of the spectrograph enable determining the abundances of 16 light elements and 20 neutroncapture elements, including thir peak element, Os. We identified Th in two objects, with [Th/Fe] values of 0.65 and 0.6, respectively, which helped us estimate their ages. The study discusses the metallicity trends of elements such as Mg, Sr, Ba, Eu, Os, and Th in both r-II and r-I objects, using a compilation of RPE objects from existing literature. We carried out a detailed line-by-line differential analysis comparing a moderately RPE object (r-I: HD107752) with an extremely RPE object (r-II: CS31082-0001) to explore the potential shared origins of their heavy element nucleosynthesis. This part of the study utilized high-resolution and high SNR spectra from the ESO-VLT’s UVES instrument, sourced from the ESO data archive. We identified three distinct patterns in the differential abundance analysis. The similar abundances of light elements up to zinc in both stars suggest a shared origin for these elements, with no odd-even variation observed. In the case of neutron-capture elements, r-I stars exhibit slightly depleted light r-process elements and more significantly depleted heavier r-process elements, challenging the theory of a single production site. We also provide plausible scenarios for their r-process enrichment. Additionally, we performed a kinematic analysis of nearly 466 r-process-enhanced stars compiled from literature, examining their origins and locations within the Milky Way. We compare the significance of our orbit-based classification of stars into different Galactic components with the Toomre diagram-based classification. Our findings indicate that RPE stars are equally distributed between the disk and halo of the Galaxy. We also utilized archival data from the ESO and KECK telescopes to explore similarities between CEMP-r/s and r-process objects and to investigate the origin of thorium in CEMP-r/s stars using machine learning algorithms. We observed that r-I and r-II stars do not distinctly separate into two groups; rather, there is an intermediate group that may consist of diluted or mixed stars. Our analysis indicate that CEMP-r/s and RPE stars are separate classes of objects. Additionally, we used the HESP, installed on the Himalayan Chandra Telescope to observe some metal-poor stars (the HESP-GOMPA Survey). This led to the discovery of numerous very metal-poor, extremely metal-poor, CEMP-r, and RPE stars. We also study the kinematics of these stars. These findings are detailed in Chapter 7 of the thesis. Our study indicates that within our range of metallicities, neutron stars mergers and supernovae are the primary sites contributing to the chemical composition of halo stars.
650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM
Topical term or geographic name entry element Galactic halo
9 (RLIN) 22902
650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM
Topical term or geographic name entry element Nucleosynthesis
650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM
Topical term or geographic name entry element Heavy elements
9 (RLIN) 13993
650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM
Topical term or geographic name entry element Stars
650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM
Topical term or geographic name entry element Himalayan Chandra Telescope
9 (RLIN) 49260
700 ## - ADDED ENTRY--PERSONAL NAME
Personal name T. Sivarani
Relator term Supervisor
9 (RLIN) 36981
856 ## - ELECTRONIC LOCATION AND ACCESS
Uniform Resource Identifier <a href="http://prints.iiap.res.in/handle/2248/8752">http://prints.iiap.res.in/handle/2248/8752</a>
Link text Click Here to Access eThesis
942 ## - ADDED ENTRY ELEMENTS (KOHA)
Source of classification or shelving scheme Universal Decimal Classification
Koha item type Thesis & Dissertations
Holdings
Withdrawn status Lost status Source of classification or shelving scheme Damaged status Not for loan Home library Current library Shelving location Date acquired Source of acquisition Cost, normal purchase price Total Checkouts Barcode Date last seen Cost, replacement price Price effective from Koha item type Purchase Price
    Dewey Decimal Classification     IIA Library-Bangalore IIA Library-Bangalore General Stacks 15/07/2025 74 0.00   20712 25/08/2025 0.00 25/08/2025 Thesis & Dissertations  

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