Domain walls in the scaling regime: Equal Time Correlator and Gravitational Waves

TL;DR

This paper uses large-scale 3D lattice simulations to study the dynamics of domain walls in the early universe, their approach to the scaling regime, and their gravitational wave signatures, revealing universal features in the GW spectrum.

Contribution

It provides the first detailed numerical analysis of the Equal Time Correlator for domain walls and links it to gravitational wave production across different cosmological backgrounds.

Findings

Scaling regime reached within a few Hubble times

Universal shape of the GW spectrum at subhorizon scales

Degree of coherence of the domain wall network inferred from GW spectra

Abstract

Domain walls are topological defects that may have formed in the early Universe through the spontaneous breakdown of discrete symmetries, and can be a strong source of gravitational waves (GWs). We perform 3D lattice field theory simulations with CosmoLattice, considering grid sizes $N = 1250$, $2048$ and $4096$, to study the dynamics of the domain wall network and its GW signatures. We first analyze how the network approaches the scaling regime with a constant $\mathcal{O}(1)$ number of domain walls per Hubble volume, including setups with a large initial number of domains as expected in realistic scenarios, and find that scaling is always reached in a few Hubble times after the network formation. To better understand the properties of the scaling regime, we then numerically extract the Equal Time Correlator (ETC) of the energy-momentum tensor of the network, thus determining its characteristic shape for the case of domain walls, and verifying explicitly its functional dependence as predicted by scaling arguments. The ETC can be further extended to the Unequal Time Correlator (UTC) controlling the GW emission by making assumptions on the coherence of the source. By comparison with the actual GW spectrum evaluated by CosmoLattice, we are then able to infer the degree of coherence of the domain wall network. Finally, by performing numerical simulations in different background cosmologies, e.g. radiation domination and kination, we find evidence for a universal ETC at subhorizon scales and hence a universal shape of the GW spectrum in the UV, while the expansion history of the Universe may instead be determined by the IR features of the GW spectrum.