Numerical analysis of melting domain walls and their gravitational waves

TL;DR

This paper investigates the evolution and gravitational wave production of melting domain walls in the early universe through numerical lattice simulations, revealing their potential role in explaining observed gravitational wave signals.

Contribution

First numerical study of melting domain walls' evolution and gravitational wave emission, showing their efficient formation, scaling behavior, and distinctive GW spectrum.

Findings

Melting domain walls form efficiently during radiation domination.

The GW spectrum has an infrared spectral index of approximately 1.6.

Results align with pulsar timing array observations, suggesting melting DWs as GW sources.

Abstract

We study domain walls (DWs) arising in field theories where $Z_2$-symmetry is spontaneously broken by a scalar expectation value decreasing proportionally to the Universe temperature. The energy density of such melting DWs redshifts sufficiently fast not to overclose the Universe. For the first time, evolution of melting DWs and the resulting gravitational waves (GWs) is investigated numerically using lattice simulations. We show that formation of closed melting DWs during radiation domination is much more efficient compared to the scenario with constant tension DWs. This suggests that it can be the main mechanism responsible for reaching the scaling regime similarly to the case of cosmic strings. However, the scaling behaviour of melting DWs is observed, provided only that the initial scalar field fluctuations are not very large. Otherwise, simulations reveal violation of the scaling law, potentially of the non-physical origin. The spectrum of GWs emitted by melting DWs is also significantly different from that of constant tension DWs. Whether the system has reached scaling or not, the numerical study reveals a GW spectrum described in the infrared by the spectral index $n \approx 1.6$ followed by the causality tail. We attribute the difference from the value $n=2$ predicted in our previous studies to a finite lifetime of the DW network. Notably, the updated index is still in excellent agreement with the recent findings by pulsar timing arrays, which confirms that melting DWs can be responsible for the observed (GW) signal. We also point out that results for evolution of melting DWs in the radiation-dominated Universe are applicable to constant tension DW evolution in the flat spacetime.