Strong CP as an Infrared Holonomy: The $\theta$ Vacuum and Dressing in Yang-Mills Theory

TL;DR

This paper reinterprets the strong CP problem by framing the vacuum angle as a global holonomy in the infrared, revealing its quantized nature and impact on global observables in Yang-Mills theory.

Contribution

It introduces a novel infrared holonomy perspective on the $ heta$ vacuum, connecting topological features with Berry phases and infrared dressing in Yang-Mills theory.

Findings

Holonomy phase quantized by integer $Q$ reproduces standard $ heta$ weight.

Global response functions depend on $ heta$, local correlators may not.

Consistent with Witten-Veneziano and rotor models.

Abstract

We reformulate the strong $CP$ problem from an infrared viewpoint in which the vacuum angle $\theta$ is not treated as a local coupling but as a global Berry-type holonomy of the infrared-dressed state space over $\mathcal{A}/\mathcal{G}$. Infrared dressing is described as adiabatic parallel transport of physical states in configuration space, generated by an infrared connection $\mathcal{A}_{\rm IR}$. Using the Chern-Simons collective coordinate, we show that the Pontryagin index emerges as an integer infrared winding, such that the resulting holonomy phase is quantized by $Q\in\mathbb Z$ and reproduces the standard weight $e^{i\theta Q}$. A quantum rotor provides a controlled infrared example illustrating why broad classes of local correlators may remain insensitive to $\theta$, while global response functions, such as the vacuum energy curvature and the topological susceptibility, retain a nontrivial dependence. We contrast this picture with recent claims of $\theta$--independence based on the order of limits and show that it is consistent with both the rotor benchmark and the classic Witten-Veneziano perspective.