Testing the viability of f(T, T) gravity models via effective equation of state constraints

Abstract

This paper rigorously examines the potential of the f(T, T) theory as a promising framework for understanding the dark sector of the universe, particularly in relation to cosmic acceleration. The f(T, T) theory extends gravitational dynamics by incorporating both the torsion scalar T and the trace of the energy-momentum tensor T. Further, we explore the functional form f(T, T) = T + β T, where β is a free parameter that modulates the matter's influence on spacetime evolution. To evaluate this model, we employ an effective EoS parameter dependent on redshift z, to solve the field equations and analyze the evolution of the Hubble parameter H(z). Using a joint dataset (H(z)+Pantheon+) and the Markov Chain Monte Carlo (MCMC) method with Bayesian analysis, we obtain the best-fit parameter values: H0 = 68.04 0.64, β = 0.14 0.17, and γ = 0.96+0.38-0.69, which align well with current observational data. Our findings indicate a deceleration parameter of q0 = -0.51, supporting a present-day accelerated expansion phase, with a transition redshift zt = 0.57 marking the universe's shift from deceleration to acceleration. Moreover, we confirm a positive cosmic fluid energy density, reinforcing stability, and find an EoS parameter value of ω0 = -0.76, consistent with quintessence-driven acceleration. These results underscore the viability of f(T, T) as a robust framework for addressing the accelerating universe and dark energy dynamics, paving the way for future investigations into its cosmological implications.