Time Evolution and Thermal Renormalization Group Flow in Cosmology

TL;DR

This paper introduces a modified finite-temperature renormalization group approach in cosmology, linking temperature to RG scale to better understand quantum effects and high-energy divergences in the universe's evolution.

Contribution

It proposes a novel thermal RG method with temperature tied to the RG scale, enabling improved analysis of quantum effects in cosmological models.

Findings

Dimensionless RG flow equations lack explicit $k$-dependence.

The approach addresses high-energy divergences of the cosmological constant.

It demonstrates a thermal phase transition solving triviality in the $$ model.

Abstract

Time-evolution of the Universe as described by the Friedmann equation can be coupled to equations of motion of matter fields. Quantum effects may be incorporated to improve these classical equations of motion by the renormalization group (RG) running of their couplings. Since temporal and thermal evolutions are linked to each other, astrophysical and cosmological treatments based on zero-temperature RG methods require the extension to finite-temperatures. We propose and explore a modification of the usual finite-temperature RG approach by relating the temperature parameter to the running RG scale as $T \equiv k_T = \tau k$ (in natural units), where $k_T$ is acting as a running cutoff for thermal fluctuations and the momentum $k$ can be used for the quantum fluctuations. In this approach, the temperature of the expanding Universe is related to the dimensionless quantity $\tau$ (and not to $k_T$). We show that by this choice dimensionless RG flow equations have no explicit $k$-dependence, as it is convenient. We also discuss how this modified thermal RG is used to handle high-energy divergences of the RG running of the cosmological constant and to "solve the triviality"of the $\phi^4$ model by a thermal phase transition in terms of $\tau$ in $d=4$ Euclidean dimensions.