String flux mechanism for fractionalization in topologically ordered phases

Abstract

We construct a family of exactly solvable spin models that illustrate a novel mechanism for fractionalization in topologically ordered phases, dubbed the string flux mechanism. The essential idea is that an anyon of a topological phase can be endowed with fractional quantum numbers when the string attached to it slides over a background pattern of flux in the ground state. The string flux models that illustrate this mechanism are Zn quantum double models defined on specially constructed d-dimensional lattices, and possess Zn topological order for d ≥ 2. The models have a unitary, internal symmetry G, where G is an arbitrary finite group. The simplest string flux model is a Z2 toric code defined on a bilayer square lattice, where G = Z2 is layer-exchange symmetry. In general, by varying the pattern of Zn flux in the ground state, any desired fractionalization class [element of H2(G, Zn)] can be realized for the Zn charge excitations. While the string flux models are not gauge theories, they map to Zn gauge theories in a certain limit, where they follow a novel magnetic route for the emergence of low-energy gauge structure. The models are analyzed by studying the action of G symmetry on Zn charge excitations, and by gauging the G symmetry. The latter analysis confirms that distinct fractionalization classes give rise to distinct quantum phases, except that classes [ω], [ω]-1 ∈ H2(G, Zn) give rise to the same phase. We conclude with a discussion of open issues and future directions.