The R\'enyi entropy and entropic cosmology

Abstract

Entropic cosmology with the R\'enyi entropy of the apparent horizon SR=(1/α)(1+α SBH), where SBH is the Bekenstein--Hawking entropy, is studied. By virtue of the thermodynamics-gravity correspondence a model of dark energy is investigated. The generalised Friedmann equations for the Friedmann--Lema\itre--Robertson--Walker spatially flat universe with the barotropic matter fluid are obtained. We compute the dark energy density D, pressure pD and the deceleration parameter q of the universe. At some model parameters the normalized density parameter of the matter m0≈ 0.315 and the deceleration parameter q0≈ -0.535 for the current epoch, which are in the agreement with the Planck data, are found. Making use of the thermodynamics-gravity correspondence, we describe the late time of the universe acceleration. The entropic cosmology considered is equivalent to cosmology based on the teleparallel gravity with the definite function F(T). The Hubble parameters are in approximate agreement (within 5 percents) with the observational Hubble data for redshifts 0.07≤ z ≤ 1.75 at the entropy parameter α≈ 0.305~GH02.