Modified cosmology from the thermodynamics of apparent horizon

TL;DR

This paper develops a modified entropy function for the apparent horizon in cosmology, enabling derivation of FLRW equations for a general matter equation of state, leading to new insights into universe evolution.

Contribution

It introduces a new entropy form that generalizes Bekenstein-Hawking entropy, allowing thermodynamic derivation of cosmological equations for arbitrary matter equations of state.

Findings

Modified Friedmann equations with new entropy form

Cosmological implications during early and late universe

Deviation from known entropy models like Tsallis and Rényi

Abstract

In the realm of the Bekenstein-Hawking entropy, the thermodynamics of apparent horizon bridges with the usual FLRW (Friedmann-Lema\^{i}tre-Robertson-Walker) equation only for a special case where the matter field is given by a perfect fluid having equation of state (EoS) parameter $= -1$, i.e $p = -\rho$ with $\rho$ and $p$ represent the energy density and the pressure of the fluid, respectively. To include the case $p \neq -\rho$, we consider the modification of the Bekenstein-Hawking entropy in the present work. In particular, we develop an entropy function that leads to the usual FLRW equations, for a $general$ EoS of the matter fluid given by $p = w\rho$, directly from the thermodynamics of the apparent horizon. The newly developed entropy acquires a correction over the Bekenstein-Hawking entropy and differs from the known entropies like the Tsallis, R\'{e}nyi, Barrow, Sharma-Mittal, Kaniadakis, and Loop Quantum Gravity entropies proposed so far. Based on this finding, we examine how the Friedmann equations of the apparent horizon cosmology are accordingly modified if one starts with a general entropy depending on the Bekenstein-Hawking entropy. This results in some interesting cosmological consequences during the early and late stages of the universe.