Study of Curvature-Matter Coupling in Modified Gravity

Abstract

Over the past century, General Relativity (GR) has been a cornerstone of gravitational theory. However, recent cosmological observations, such as the accelerated expansion of the Universe, challenge its completeness and the standard model. This has motivated the development of alternative approaches, including dynamical dark energy and modifications to gravity. This thesis investigates the f(R, Lm) gravity framework, which extends f(R) gravity by introducing curvature-matter coupling, to address unresolved issues in modern cosmology. Chapter 1 reviews the foundations of cosmology, GR, and , discussing their challenges and introducing modified gravity theories. Chapter 2 studies cosmic expansion in a specific non-linear f(R, Lm) model, analyzing its dynamics using updated H(z) and Pantheon datasets and demonstrating a deceleration-to-acceleration transition. Chapter 3 introduces a model-independent Hubble parameter parametrization and explores cosmological variables using MCMC and combined data. Chapter 4 incorporates bulk viscosity into f(R, Lm) models to explain late-time acceleration and applies Om diagnostics and energy conditions. Chapter 5 examines non-singular matter bounce cosmologies, analyzing bouncing dynamics and the evolution of cosmographic parameters. Chapter 6 addresses gravitational baryogenesis and shows how f(R, Lm) gravity supports the observed baryon-to-entropy ratio. Chapter 7 summarizes the results and suggests directions for future work.