Quintessence phase of the late-time Universe in f(Q,T) gravity

Abstract

In this paper, we have studied the late-time accelerating expansion of the Universe using the matter-geometry coupled f(Q, T) gravity model, where Q is the non-metricity scalar and T represents the trace of the energy-momentum tensor. We constrain the best-fit values of cosmological parameters m0, H0, α0~and~ β0 through the Monte Carlo Markov Chain (MCMC) simulation using 31 Hubble parameter data points from cosmic chronometers (CC) and 26 data points from baryon acoustic oscillations (BAO), making a total of 57 datasets (labeled CC+BAO), as well as SNIa distance moduli measurements from the Pantheon+ sample, which consists of 1701 light curves of 1550 distinct supernovae (labeled Pantheon +SHOES), and their combination (labeled CC+BAO+Pantheon +SHOES). We compare our constrained Hubble constant H0 value with different late-time and early-time cosmological measurements. Deceleration parameter \(q(z)\), effective equation of state parameters \(weff(z)\), Hubble parameter H(z), and distance modulus \(μ(z)\) are numerical results of dynamical quantities that show that the f(Q, T) gravity model is compatible with a transition towards a quintessence-like phase in the late-time. In conformity with \(\)CDM, we moreover take into account the geometrical interpretations by considering the state-finder parameters \(r-s\) and \(r-q\), which are crucial parameters for additional analysis. Additionally, the statistical analysis has been carried out for further investigation.

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