Abstract
Using f(T) gravitational theory, we construct modified cosmological models via the first law of thermodynamics by using the non-extensive thermodynamics framework, the effects of which are captured by the parameter δ. The resulting cosmological equations are modified compared to the standard Einstein-Hilbert ones, with the modifications coming from the f(T) gravitational theory and from the non-extensive parameter which quantifies the non-extensive thermodynamics effects quantified by the parameter δ, which when is set equal to unity, one recovers the field equations of f(T) gravity. We study in detail the cosmological evolution of the model in the presence of collisionless non-relativistic matter case, and we derive the exact forms of the dark energy density parameter and of the dark energy equation of state parameter, from which we impose constraints on the non-extensive thermodynamics parameter, δ, by using the Planck 2018 data on cosmological parameters. Accordingly, we repeat our calculations after including the relativistic matter along with the non-relativistic one, and we derive the new forms of the dark energy density parameter and of the dark energy equation of state parameter. Our study shows that the inclusion of non-extensive thermodynamic effects, quantified by the parameter δ, for a flat Friedmann-Robertson-Walker Universe, has measurable differences compared with the normal thermodynamics case. We confront our results with Type Ia supernovae observations for z≥0.4 and we obtain reasonably agreement with the observational data.
Highlights
Historical Review and Introductory RemarksThe focus of this work is on the study of non-extensive thermodynamics effects in f ( T ) modified gravity
We shall be interested in the matter–energy density parameter Ωm (z), the dark energy density parameter Ω DE (z), the dark energy equation of state (EoS) parameter w DE (z) and the deceleration parameter q(z)
All these quantities are calculated in the absence of relativistic matter and we shall leave as free parameter the non-extensive parameter δ which is constrained by the non-extensive statistics [4] and it is believed that it should be greater than unity [94,95]
Summary
The focus of this work is on the study of non-extensive thermodynamics effects in f ( T ) modified gravity. In the present work we are going to investigate the effect of non-extensive thermodynamics on a specific modified gravity, the f ( T ) gravitational theory. There are many interesting studies in the context of f ( T ) gravity in order to describe dark energy and dark matter [54,55,56,57,58,59,60,61] It is the aim of the present paper to study for the first time the effect of non-extensive thermodynamics on the cosmology of f ( T ) gravity. The study of a cosmological model including radiation is presented in Section 3.2 and the modified energy-density and pressure that contains the effect of the non-extensive thermodynamics are derived. We will define shortly the black hole entropy (Hawking version) and the non-extensive form, and use this to the modified gravity field equations by using the first thermodynamic law. This is the first appearance of the effect of Tsallis entropy in f ( T ) gravity, and Cis a constant of integration
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