Axion Quality Problem Alleviated by Non-Minimal Coupling to Gravity

TL;DR

This paper explores how a non-minimal coupling of the Peccei-Quinn field to gravity can suppress gravitational instanton effects, potentially preserving the U(1) symmetry and solving the axion quality problem.

Contribution

It demonstrates that a sufficiently large non-minimal coupling to gravity can mitigate gravitational symmetry breaking effects in axion models.

Findings

Suppression of U(1)-breaking effects for ξ > 2000

Non-minimal coupling can preserve global symmetry quality

Provides a new approach to the axion quality problem

Abstract

Global symmetries are expected to be violated by gravity, which may cause a serious problem to models based on these symmetries. A famous example is the Peccei-Quinn solution to the strong CP problem in QCD axion models; it requires a global U(1) symmetry to be respected with high quality, and even the Planck-scale suppressed operators that violate the U(1) symmetry would spoil this solution. Indeed, it is known that gravitational instantons do break the U(1) Peccei-Quinn symmetry and induce the U(1)-violating operators, bringing back the strong CP problem to the axion models. This conclusion is, however, dependent highly on the structure of the theory around the Planck scale and, therefore, may be evaded if we go beyond the minimal setup. In this paper, we study the effect of a non-minimal coupling of the Peccei-Quinn field to gravity, $\xi$, on the gravitational instanton effect. This setup is frequently considered in cosmology as it can realize a successful inflation if $\xi \lesssim 10^5$. We find that the U(1)-breaking effect of the gravitational instantons can sufficiently be suppressed for $\xi \gtrsim 2 \times 10^3$, which suggests that the U(1) symmetry may be maintained with high quality even in the presence of gravity. Our result thus points to a new way to avoid the quality problem of global symmetries.