Astrophysical Objects in Modified Theories of Gravity

TL;DR

This thesis explores the structure, stability, and observational signatures of neutron and strange stars within modified gravity theories like f(Q) and f(T), employing analytical solutions, stability criteria, and Bayesian data analysis.

Contribution

It introduces new models of compact stars in modified gravity frameworks, utilizing gravitational decoupling techniques and observational constraints to assess their physical viability.

Findings

Modified gravity significantly impacts stellar mass and radius.

Models are consistent with observational data like NICER measurements.

Bayesian analysis constrains parameters of alternative gravity theories.

Abstract

This thesis investigates compact astrophysical objects within modified theories of gravity, focusing on neutron stars and strange stars. The work studies their internal structure, equilibrium, and stability in gravitational frameworks based on torsion and nonmetricity, which provide the foundation for theories such as \(f(Q)\) and \(f(T)\) gravity. Charged isotropic compact star models are constructed in \(f(Q)\) gravity using conformal symmetry and the MIT Bag equation of state, with matching to the Bardeen exterior spacetime. Gravitational decoupling techniques, including minimal and complete geometric deformation methods, are employed in \(f(T)\) gravity to generate anisotropic strange star models. These approaches enable the inclusion of additional gravitational sources, dark matter effects, and spacetime deformations. Exact analytical solutions are obtained under suitable physical conditions such as regularity and vanishing complexity. The models are examined using energy conditions, causality constraints, the generalized Tolman--Oppenheimer--Volkoff equation, and Herrera's cracking criterion to ensure physical viability and stability. The influence of modified gravity parameters on stellar mass, radius, compactness, and stability is analyzed in detail. A Bayesian statistical framework is applied to constrain model parameters using observational data, including NICER mass--radius measurements. Bayes factor analysis is further used to identify viable gravitational extensions consistent with astrophysical observations. The results show that modified gravity can significantly affect the maximum mass, radius, and stability of compact stars while remaining compatible with observations. This work provides a systematic theoretical and observational study of compact stars beyond general relativity.