Study of Compact Stars and their Properties based on General Relativistic Core-Envelope Models

TL;DR

This thesis investigates the properties, classification, and stability of neutron stars using general relativistic core-envelope models, revealing new insights into their structure, stability, and potential link to starquakes and gamma-ray bursts.

Contribution

It introduces a novel classification of compact stars based on radii and explores the effects of anisotropy and perturbations on their stability and starquake potential.

Findings

Classified neutron stars into three categories by radius.

Derived mass-radius relationships using Einstein's equations.

Linked envelope strain energy to gamma-ray burst energies.

Abstract

This thesis explores compact objects, particularly neutron stars, focusing on their properties, classification, and stability within the framework of general relativity. Two distinct studies are presented. The first study examines the properties of compact stars, including neutron stars, using an equation of state from a core-envelope model. By solving Einstein's equations with pseudo-spheroidal and spherically symmetric geometries, the mass-radius relationship is derived, leading to the classification of compact stars into three categories: highly compact self-bound stars (radii $<$ 9 km), normal neutron stars (radii 9--12 km), and soft matter neutron stars (radii 12--20 km). Other parameters such as Keplerian frequency, surface gravity, and gravitational redshift are also computed, offering insights into highly compact neutron stars with exotic compositions. The second study investigates the impact of density perturbations and local anisotropy on stellar stability. Using the cracking concept and a core-envelope model with anisotropic pressure in the envelope, we explore the potential of these configurations as progenitors for starquakes. The buildup of strain energy in the envelope, linked to anisotropy, can reach up to $10^{50}$ erg -- comparable to energy released in giant gamma-ray bursts. This study thus contributes to understanding the relationship between starquakes and gamma-ray bursts. Overall, this work advances the understanding of neutron stars by classifying them based on their radii and investigating the stability of their matter structures, providing new insights into starquakes and their possible connections with gamma-ray bursts.