Irreversible thermodynamic description of dark matter and radiation creation during inflationary reheating

TL;DR

This paper models the matter creation process during inflationary reheating using irreversible thermodynamics, analyzing how scalar field decay generates matter and influences cosmic acceleration and deceleration phases.

Contribution

It introduces a thermodynamic framework for describing matter creation during reheating, combining gravitational equations with irreversible thermodynamics, and analyzes different scalar field potentials.

Findings

Matter densities peak at reheating temperature.

Particle production accelerates the Universe during reheating.

Post-reheating, the Universe decelerates and inflation ends gracefully.

Abstract

We investigate the matter creation processes during the reheating period at the end of inflation in the early Universe, by using the irreversible thermodynamic of open systems. The matter content of the Universe is assumed to consist of the inflationary scalar field, which, through its decay, generates relativistic matter, and pressureless dark matter, respectively. At the early stages of reheating the inflationary scalar field transfers its energy to the newly created matter particles, with the field energy decreasing to near zero. The general equations governing the irreversible matter creation during reheating are obtained by combining the thermodynamics description of the matter creation and the gravitational field equations. A dimensionless form of the general system of the reheating equations is also introduced. The role of the different inflationary scalar field potentials is analyzed by using analytical and numerical methods, and the evolution of the matter and scalar field densities, as well as of the cosmological parameters during reheating, are obtained. Typically, the values of the energy densities of relativistic matter and dark matter reach their maximum when the Universe is reheated up to the reheating temperature, which is determined for each case, as a function of the scalar field decay width, the scalar field particle mass, and of the cosmological parameters. An interesting result is that particle production leads to the acceleration of the Universe during the reheating phase, with the deceleration parameter showing a complex dynamics. Once the energy density of the scalar field becomes negligible with respect to the matter densities, the expansion of the Universe decelerates, and inflation has a graceful exit after reheating.