Fractal Subsystem Symmetries, Anomalies, Boundaries, and Effective Field Theory

TL;DR

This paper explores three-dimensional topological phases with fractal subsystem symmetries, revealing complex ground state degeneracies, boundary phenomena, and an effective field theory capturing their unique fracton physics.

Contribution

It introduces a detailed analysis of fractal subsystem symmetries in 3D topological phases, including ground state degeneracy, boundary physics, and a derived effective field theory.

Findings

Ground state degeneracy depends on plane sizes, indicating UV/IR mixing.

Boundary physics elucidates connections to 2D phases.

Effective field theory captures fractal symmetries and anomalies.

Abstract

This work reports an extensive study of three-dimensional topological ordered phases that, in one of the directions behave like usual topological order concerning mobility of excitations, but in the perpendicular plane manifest type-II fracton physics dictated by a fractal subsystem symmetry. We obtain an expression for the ground state degeneracy, which depends intricately on the sizes of the plane, signaling a strong manifestation of ultraviolet/infrared (UV/IR) mixing. The ground state degeneracy can be interpreted in terms of spontaneous/explicit breaking of fractal subsystem symmetries. We also study the boundary physics, which in turn is useful to understand the connection with certain two-dimensional phases. Finally, we derive a low-energy but not long-distance effective field theory, by Higgsing a fractal $U(1)$ symmetry and taking the deep IR limit. This description embodies in a natural way several aspects of the phases, such as the content of generalized global symmetries, the role of fractal symmetries on the mobility of excitations, the anomalies, and the boundary physics.