Exploring the Universe Expansion History with f(R,T) Gravity: Constraints on Cosmological Parameters

Abstract

This work examines the cosmological implications of two functional forms of f(R,T) = R + α Tn gravity: for two different value of n where n=1 and n≠ 1, and α and n are free parameters. The modified Friedmann equations are derived, and the cosmic evolution of the Hubble parameter H(z) is determined. Cosmological parameters are estimated through 2 minimization and MCMC analysis using the emcee algorithm, with model parameters constrained by various observational datasets. Both models reproduce late-time acceleration and remain observationally indistinguishable from , while allowing small deviations parameterized by α and n. The cosmological behavior of the deceleration parameter q(z), the jerk, the snap parameter s(z), and the effective equation of state parameter ω is also analyzed. The results indicate that the Universe transitioned from deceleration to late-time accelerated expansion, consistent with the model. Analysis of the energy conditions reveals that the NEC and DEC are satisfied, while the SEC is violated, which explains the transition from a decelerating matter-dominated epoch to the present accelerated phase. These findings indicate that the proposed f(R,T) models are compatible with current observational data and provide a viable alternative to in describing cosmic acceleration.