The Higher Structure of Symmetries of Axion-Maxwell Theory: Unveiling the Interplay of Topological Defects and Non-invertible Symmetries

The paper focuses on Axion-Maxwell theory in four dimensions as a case study to explore the intricate structure of non-invertible symmetries in quantum field theories. The key findings and their potential for generalization are: Non-invertible symmetries from non-conserved currents: The paper demonstrates how non-invertible symmetries can arise even when the associated currents are not conserved. This occurs when the current's divergence is proportional to a topological current, allowing for the construction of topological defects by coupling to lower-dimensional theories with appropriate anomalies. This mechanism could be applicable to other theories with similar current structures, such as gauge theories with topological terms or theories with generalized global symmetries. Higher-group structure and junctions: The interplay between invertible and non-invertible symmetries in Axion-Maxwell theory leads to a rich higher-group structure. This manifests in the existence of topological junctions between defects of different symmetries, governed by the anomaly cancellation conditions. The paper explicitly describes the junctions between electric, magnetic, shift, and winding defects. This approach to understanding the higher-categorical structure of symmetries through their junctions and anomaly interplay could be extended to other theories with multiple interacting symmetries. Half-gauging and duality defects: The paper utilizes the concept of half-gauging to construct non-invertible defects. This involves gauging a discrete subgroup of a symmetry in half of spacetime, leading to a defect at the boundary. These defects are often related to duality defects, which implement duality transformations on the fields. This connection between non-invertible symmetries, half-gauging, and dualities could be a fruitful avenue for exploring non-invertible symmetries in other self-dual theories or theories with known duality webs. Generalization to higher-form symmetries: While the paper focuses on 0-form and 1-form symmetries, the techniques and concepts used, such as minimal theory couplings and inflow actions, are applicable to higher-form symmetries as well. This opens up the possibility of studying non-invertible higher-form symmetries in diverse dimensions and theories. In summary, the findings in this paper provide a blueprint for investigating non-invertible symmetries in other quantum field theories. By analyzing current structures, anomaly cancellation conditions, duality properties, and higher-group structures, one could potentially uncover similar rich symmetry structures in a broader class of theories.

Yes, the higher categorical structure of symmetries has the potential to revolutionize the classification of quantum field theories (QFTs), going beyond traditional methods that rely primarily on Lie groups and their representations. Here's how: Refinement of traditional classifications: Traditional methods often fail to distinguish between theories with identical Lie group symmetries but different symmetry realizations or 't Hooft anomalies. The higher categorical structure, encoding information about defects, junctions, and their fusion properties, can differentiate between such theories. For example, different realizations of a ℤN symmetry can be distinguished by the braiding statistics of their associated defects. Unveiling hidden symmetries: Non-invertible symmetries, often not captured by traditional methods, can be revealed through their higher categorical structure. This can lead to the discovery of new dualities, as non-invertible symmetries can map to different-looking but equivalent descriptions of the same theory. Categorical invariants: The higher categorical structure of symmetries provides new invariants that can be used to characterize and classify QFTs. These invariants, such as F-symbols, braiding statistics, and fusion categories, capture the topological properties of defects and their interactions, offering a more refined classification scheme. Constraints on RG flows: The higher categorical structure of symmetries is expected to be preserved under renormalization group (RG) flows. This implies that theories connected by an RG flow must have compatible symmetry categories, providing strong constraints on possible flows and the space of QFTs. Unification of different types of symmetries: The categorical framework provides a unified language for describing various types of symmetries, including global, gauge, higher-form, and even spacetime symmetries. This could lead to a more holistic understanding of symmetries and their role in constraining the dynamics of QFTs. While still under development, the study of higher categorical structures in QFT is a rapidly evolving field with the potential to significantly impact our understanding and classification of these theories. It offers a powerful new lens through which to view the intricate web of dualities, anomalies, and symmetry realizations that govern the behavior of quantum fields.

The exploration of non-invertible symmetries and their higher categorical structure in quantum field theories, as exemplified by the Axion-Maxwell theory, holds intriguing implications for our understanding of the early universe and fundamental physics: Phase transitions and cosmic defects: Non-invertible symmetries can be spontaneously broken or restored during cosmological phase transitions. This could lead to the formation of cosmic defects, such as domain walls, cosmic strings, or more exotic objects, with potentially observable signatures in the cosmic microwave background radiation or gravitational wave signals. Axion physics and dark matter: Axion-Maxwell theory is a central player in axion physics, where the axion is a promising dark matter candidate. Understanding the full symmetry structure of this theory, including its non-invertible aspects, could provide new insights into axion interactions, production mechanisms in the early universe, and potential detection strategies. Confinement and topological phases: Non-invertible symmetries are known to play a crucial role in characterizing and understanding topological phases of matter and the phenomenon of confinement in gauge theories. The insights gained from studying these symmetries in simpler settings like Axion-Maxwell theory could potentially shed light on the more complex dynamics of quantum chromodynamics (QCD) and the nature of quark confinement. Beyond the Standard Model physics: The Standard Model of particle physics, while remarkably successful, leaves several phenomena unexplained, such as the origin of neutrino masses, the nature of dark matter, and the hierarchy problem. Extensions of the Standard Model often involve new symmetries and particles. Exploring non-invertible symmetries could inspire novel model-building directions and provide new tools for understanding the dynamics of these theories. Quantum gravity and holography: The higher categorical structure of symmetries is also relevant for understanding quantum gravity and its holographic duality with conformal field theories. Non-invertible symmetries in the boundary theory could correspond to subtle quantum gravitational effects in the bulk, potentially offering new insights into the nature of spacetime and quantum gravity. While the connection between these abstract concepts and concrete physical phenomena is still under active investigation, the study of non-invertible symmetries and their intricate structure holds significant promise for deepening our understanding of the universe's fundamental building blocks and its evolution.