Multi-Instantons, Multi-Axions, and Non-Invertible Symmetries in 4d QFT

TL;DR

This paper develops a comprehensive framework for understanding non-invertible symmetries in 4d quantum field theories with multiple instantons and axions, unifying various approaches and extending their applicability to phenomenology.

Contribution

It introduces a novel partial gauging method, generalizes half-space gauging, and provides a Lagrangian formulation for non-invertible symmetries in multi-instanton and multi-axion theories.

Findings

Unified framework for non-invertible symmetries in 4d QFTs.

Explicit construction of symmetry actions on 't Hooft lines and axion strings.

Extension of non-invertible Gauss law to theories with multiple axions.

Abstract

We study non-invertible global symmetries in 4d quantum field theories, aiming to generalize existing discussions to theories with multiple instantons and axions, and to make the subject more accessible to particle phenomenology. Building on both the Adler-Bell-Jackiw (ABJ) anomaly construction and the half-space gauging approach, we identify the 3d topological quantum field theories required to describe non-invertible symmetries in the presence of multi-instanton effects. To this end, we introduce a method we call partial gauging and show that partial gauging of 3d Chern-Simons theories naturally leads to anomaly inflow actions with general ABJ anomaly matrices. We further generalize the half-space gauging construction to the case of multiple gauge sectors and compute correlation functions of boundary line operators. This enables us to analyze the action of non-invertible operators on various species of 't Hooft lines and to interpret the results in terms of the Witten effect. For theories with multiple axions, we determine both the non-invertible 0-form and 1-form symmetries, as well as their actions on axion strings and 't Hooft lines, thereby generalizing the previously known notion of the non-invertible Gauss law. Our framework unifies several previously disparate constructions, provides a concrete Lagrangian-based formulation of non-invertible symmetries, and naturally extends to theories with multiple instantons and axions, which are of both phenomenological and theoretical interest. These results may also find broader applications in beyond-the-Standard-Model scenarios.