Accelerated Expansion of the Universe in Nonmetricity-based Modified Gravity

Abstract

This thesis explores the cosmological implications of modified gravity, focusing on nonmetricity-based f(Q) gravity as an alternative to the model in explaining cosmic acceleration. Chapter I lays the theoretical groundwork by reviewing General Relativity (GR), , and the limitations of the standard model, motivating f(Q) gravity. Chapter II constructs cosmological reconstructions of f(Q) gravity within the FLRW framework, deriving forms of f(Q) that replicate the expansion and using the e-folding parameter to show compatibility with various cosmic histories. Chapter III addresses challenges with arbitrary f(Q) forms by applying Gaussian Process (GP) reconstruction using observational Hubble data. This model-independent method reconstructs the Hubble parameter H(z), leading to a data-driven f(Q) form. Motivated by this, a new parametrization f(Q) = -2 + ε Q2 is proposed, and power-law and exponential models are tested for consistency. Chapter IV incorporates a quintessence scalar field in power-law f(Q) gravity to study inflation and late-time acceleration. Using GP, the scalar potential V(φ) is reconstructed and analyzed. Results show that early dark energy has little impact today, but reconstructed quintessence models offer insights into cosmic acceleration. Chapter V examines interacting dark energy and matter under power-law f(Q) using dynamical systems. Two interaction types are studied, and fixed points linked to de Sitter and quintessence solutions are identified. Chapter VI concludes and suggests future work.

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