Regulating the infrared by mode matching: A massless scalar in expanding spaces with constant deceleration

TL;DR

This paper addresses infrared divergences in a massless scalar field in expanding spacetimes by matching to a non-divergent spacetime, ensuring finite correlation functions and analyzing quantum backreaction effects.

Contribution

It introduces a mode matching method to regulate infrared divergences in scalar fields on expanding backgrounds, providing a new way to define the vacuum and compute physical quantities.

Findings

Correlation functions are infrared finite after matching.

Quantum energy density dilutes similarly or faster than background energy.

Infrared regulation via matching aligns with finite box results in accelerating universes.

Abstract

In this paper we consider a massless scalar field, with a possible coupling $\xi$ to the Ricci scalar in a $D$ dimensional FLRW spacetime with a constant deceleration parameter $q=\epsilon-1$, $\epsilon=-{\dot{H}}/{H^2}$. Correlation functions for the Bunch-Davies vacuum of such a theory have long been known to be infrared divergent for a wide range of values of $\epsilon$. We resolve these divergences by explicitly matching the spacetime under consideration to a spacetime without infrared divergencies. Such a procedure ensures that all correlation functions with respect to the vacuum in the spacetime of interest are infrared finite. In this newly defined vacuum we construct the coincidence limit of the propagator and as an example calculate the expectation value of the stress energy tensor. We find that this approach gives both in the ultraviolet and in the infrared satisfactory results. Moreover, we find that, unless the effective mass due to the coupling to the Ricci scalar $\xi R$ is negative, quantum contributions to the energy density always dilute away faster, or just as fast, as the background energy density. Therefore, quantum backreaction is insignificant at the one loop order, unless $\xi R$ is negative. Finally we compare this approach with known results where the infrared is regulated by placing the Universe in a finite box. In an accelerating universe, the results are qualitatively the same, provided one identifies the size of the Universe with the physical Hubble radius at the time of the matching. In a decelerating universe however, the two schemes give different late time behavior for the quantum stress energy tensor. This happens because in this case the length scale at which one regulates the infrared becomes sub-Hubble at late times.