Metaplectic Anyons, Majorana Zero Modes, and their Computational Power

Abstract

We introduce and study a class of anyon models that are a natural generalization of Ising anyons and Majorana fermion zero modes. These models combine an Ising anyon sector with a sector associated with SO(m)2 Chern-Simons theory. We show how they can arise in a simple scenario for electron fractionalization and give a complete account of their quasiparticles types, fusion rules, and braiding. We show that the image of the braid group is finite for a collection of 2n fundamental quasiparticles and is a proper subgroup of the metaplectic representation of Sp(2n-2,Fm) H(2n-2,Fm), where Sp(2n-2,Fm) is the symplectic group over the finite field Fm and H(2n-2,Fm) is the extra special group (also called the (2n-1)-dimensional Heisenberg group) over Fm. Moreover, the braiding of fundamental quasiparticles can be efficiently simulated classically. However, computing the result of braiding a certain type of composite quasiparticle is # P-hard, although it is not universal for quantum computation because it has a finite braid group image. This a rare example of a topological phase that is not universal for quantum computation through braiding but nevertheless has # P-hard link invariants. We argue that our models are closely related to recent analyses finding non-Abelian anyonic properties for defects in quantum Hall systems, generalizing Majorana zero modes in quasi-1D systems.