Dark energy constraint on equation of state parameter in the Weyl type f(Q,T) gravity

Abstract

The equation of state parameter is a significant method for characterizing dark energy models. We investigate the evolution of the equation of state parameter with redshift using a Bayesian analysis of recent observational datasets (the Cosmic Chronometer data (CC) and Pantheon samples). The Chevallier-Polarski-Linder parametrization of the effective equation of state parameter, ωeff=ω0+ωa ( z1+z) , where ω0 and ωa are free constants, is confined to the Weyl type f(Q,T) gravity, where Q represents the non-metricity and T is the trace of the energy-momentum tensor. We observe the evolution of the deceleration parameter q, the density parameter , the pressure p, and the effective equation of state parameter ω. The cosmic data limit for ω does not exclude the possibility of ω < -1. It is seen that the parameter ω shows a transition from deceleration to acceleration, as well as a shift from ω>-1 to ω<-1.