Probing High-Quality Axions with Gravitational Waves

Abstract

We present a systematic study of gravitational wave (GW) signals from phase transitions and topological defects in a unified high-quality axion framework. The gauged U(1)g symmetry forbids any bias term that could lift the vacuum degeneracy, restricting the theory to the phenomenologically viable case N DW=1. Requiring the axion to account for the observed dark matter (DM) abundance and satisfy the high-quality condition constrains the gauge symmetry-breaking scale to fg ∈ [1.6×1011,\,1016]\,GeV for the QCD axion, leading to a well-defined band of GW signals, part of which is consistent with current pulsar timing array observations. Two-step first-order phase transitions are common in this framework, with the lower-scale transition generating GWs with f peak O(107)\,Hz. For axion-like realizations, generic post-inflation models predict GW spectra that are nearly degenerate with the QCD axion case. We conclude that GWs alone cannot distinguish between these scenarios, highlighting the need for complementary probes.