Axion Cosmology with Multi-Branch Yang-Mills

TL;DR

This paper explores how the multi-branched vacuum structure of Yang-Mills theories influences axion cosmology, leading to novel phenomena such as phase transitions and gravitational waves, especially relevant for high decay constant axions in the string Axiverse.

Contribution

It demonstrates the impact of Yang-Mills multi-branch vacua on axion cosmology, revealing new phase transition phenomena and potential observable signals like gravitational waves.

Findings

Discovery of new first-order phase transitions

Prediction of gravitational-wave backgrounds from phase transitions

Potential formation of primordial black holes

Abstract

It is known that Yang-Mills theories, especially in the large-$N$ limit, exhibit a $\theta$-vacuum structure with a multi-branched vacuum energy. In this work, we demonstrate that this multi-branch structure can play a crucial role in axion cosmology when the axion acquires its mass from the Yang-Mills sector, even when that sector is never reheated by the inflaton. The key observation is that the axion potential is directly tied to the tunneling rate between adjacent branches. We find qualitatively new phenomena, including a new class of first-order phase transitions, bouncing bubbles, and nested "bubbles-within-bubbles." When the axion has a decay constant around the Planck scale, as motivated by the string Axiverse, the axion can be driven near the hilltop by inflationary dynamics, allowing the phase transition to be triggered. The associated energy release can be large enough to generate a significant stochastic gravitational-wave background, produce primordial black holes, or populate the Yang-Mills sector with particles. These phenomena represent novel predictions of the Axiverse and should be taken into account when assessing the cosmological impact of axions or axion-like particles. To recover conventional axion cosmology, one must suppress or avoid the dynamics discussed in this work.