Cosmological scenario based on the first and second laws of thermodynamics: Thermodynamic constraints on a generalized cosmological model

Abstract

The first and second laws of thermodynamics should lead to a consistent scenario for discussing the cosmological constant problem. In the present study, to establish such a thermodynamic scenario, cosmological equations in a flat Friedmann-Lema\itre-Robertson-Walker universe were derived from the first law, using an arbitrary entropy SH on a cosmological horizon. Then, the cosmological equations were formulated based on a general formulation that includes two extra driving terms, f(t) and hB(t), which are usually used for, e.g., time-varying (t) cosmology and bulk viscous cosmology, respectively. In addition, thermodynamic constraints on the two terms are examined using the second law of thermodynamics, extending a previous analysis [Phys. Rev. D 99, 043523 (2019) (arXiv:1810.11138)]. It is found that a deviation S of SH from the Bekenstein-Hawking entropy plays important roles in the two terms. The second law should constrain the upper limits of f(t) and hB(t) in our late Universe. The orders of the two terms are likely consistent with the order of the cosmological constant obs measured by observations. In particular, when the deviation S is close to zero, hB(t) and f(t) should reduce to zero and a constant value (consistent with the order of obs), respectively, as if a consistent and viable scenario could be obtained from thermodynamics.

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