High-quality Peccei-Quinn symmetry from the interplay of vertical and horizontal gauge symmetries (2503.16648v1)

Abstract: We explore a class of axion models where an accidental $\mathrm{U}(1)$ Peccei-Quinn (PQ) symmetry automatically emerges from the interplay of vertical (grand-unified) and horizontal (flavor) gauge symmetries. Focusing on a specific Pati-Salam realization, we analyze the quality of the PQ symmetry and demonstrate that the model non-trivially reproduces the Standard Model flavor structure. In the pre-inflationary PQ-breaking scenario, the axion mass window is predicted to be $m_a \in [2 \times 10^{-8}, 10^{-3}]\,\mathrm{eV}$. A high-quality axion, immune to the PQ quality problem, is obtained instead for $m_a \gtrsim 0.01\,\mathrm{eV}$, corresponding to a post-inflationary PQ-breaking scenario. A distinctive feature of this setup is the presence of parametrically light fermions, known as anomalons, which are introduced to cancel the gauge anomalies of the flavor symmetry. For the most favorable values of the PQ-breaking scale needed to address the PQ quality problem, the anomalons are expected to have masses below the eV scale. We further investigate their cosmological production in the early universe, highlighting how measurements of $\Delta N_{\rm eff}$ could serve as a low-energy probe of the ultraviolet dynamics addressing the PQ quality problem.