A new parametric observational study of $f(Q,B)$ gravity with modified chaplygin gas

TL;DR

This paper investigates a modified gravity model combining $f(Q,B)$ gravity with Modified Chaplygin Gas, deriving analytical solutions and fitting them to observational data to explain late-time cosmic acceleration.

Contribution

It introduces a new parametric $f(Q,B)$ gravity model with MCG, deriving analytical $H(z)$, and performs observational constraints using recent cosmological data.

Findings

Best-fit Hubble constant $H_0=72.22$ km/s/Mpc

Deceleration parameter transition at $z_{tr} \\approx 0.946$

Universe age estimated at approximately 13.53 Gyr

Abstract

In this work, we explore the cosmological dynamics of a modified gravity framework based on the function $f(Q,B)=\delta Q^{2}+\beta B$, where $Q$ denotes the nonmetricity scalar and $B$ is the boundary term that relates $Q$ to the Ricci scalar. The matter sector is modeled using the Modified Chaplygin Gas (MCG) with the equation of state $p=A\rho-\frac{B}{\rho^{\alpha}}$, allowing the model to interpolate between early-time matter behavior and late-time cosmic acceleration. By deriving an analytical expression for the Hubble parameter $H(z)$, we perform a parameter estimation using Markov Chain Monte Carlo (MCMC) techniques in conjunction with the latest cosmological observations: $46$ Hubble parameter measurements, $15$ BAO data points, DESI DR2 BAO data and the Pantheon+ Type Ia supernovae compilation. The best-fit values are obtained as $H_0 = 72.22^{+3.64}_{-4.46}$, $A_s = 0.696^{+0.082}_{-0.129}$, $\alpha = 0.0029^{+0.022}_{-0.021}$, and $A = 0.0038^{+0.071}_{-0.047}$. The deceleration parameter transitions at redshift $z_{tr} \approx 0.946$, while the present-day value is $q_0 = -0.789$. The model yields an age of the Universe $t_0 \approx 13.53$ Gyr and a present EoS parameter $\omega_0 \approx -0.691$, which reflects the late-time acceleration consistent with observational bounds. These results demonstrate that the MCG scenario within $f(Q,B)$ gravity provides a viable and observationally consistent framework for explaining the late-time accelerated expansion of the Universe.