Non-flat and non-Extensive Thermodynamic Effects of M{\o}ller tetradic theory of gravitation on cosmology

TL;DR

This paper explores how M{ }ller tetradic theory of gravitation influences non-flat cosmological models, incorporating non-extensive thermodynamics, and examines their effects on universe evolution, dark energy, and thermodynamic properties.

Contribution

It introduces non-flat cosmological models within M{ }ller's tetradic theory using non-extensive thermodynamics, highlighting the impact of new parameters on universe dynamics.

Findings

Non-flat models are affected by the free parameter $$ in MTT.

Non-extensive thermodynamics significantly alters cosmological evolution.

Open universe deceleration mimics dark energy behavior at late times.

Abstract

We derive non-flat cosmological models for two cases (i.e., dust and radiation) in the context of M{\o}ller's tetradic theory (MTT) of gravitation using the tetrad that creates the non-flat Friedmann-Robertson-Walker (FRW) metric. These two models are affected by the free dimensional parameter, $\lambda$, that characterized MTT, which approaches zero in the flat case for both models. Using standard definitions of thermodynamics, we calculate the radius horizon, Hawking temperature, and entropy of our non-flat models in the framework of cosmology and show the effect of $\lambda$ on open and closed universes. We then use the first law of thermodynamics to construct non-flat cosmological models via the non-extensive thermodynamic approach. The resulting models are affected by $\lambda$ and the extensive parameter, $\delta$, which quantifies the effect of non-extensive thermodynamics. When we set, $\lambda=0$ and $\delta=1$, we return to Einstein's general relativity models. We study the evolution of our models in the presence of collisionless non-relativistic matter and describe precise forms of the dark energy density and equation-of-state parameter constraining the non-extensive thermodynamic parameter. We show that insertion of the non-extensive thermodynamic parameter affects the non-flat FRW universe in a manner that noticeably differs from that observed under normal thermodynamics. We also show that the deceleration of the open universe behaves as dark energy in a future epoch, i.e., when the redshift approaches -1, i.e., $z\approx$-1.