English

Quantum double aspects of surface code models

Quantum Physics 2022-05-04 v1 Mathematical Physics math.MP Quantum Algebra

Abstract

We revisit the Kitaev model for fault tolerant quantum computing on a square lattice with underlying quantum double D(G)D(G) symmetry, where GG is a finite group. We provide projection operators for its quasiparticles content as irreducible representations of D(G)D(G) and combine this with D(G)D(G)-bimodule properties of open ribbon excitation spaces L(s0,s1)L(s_0,s_1) to show how open ribbons can be used to teleport information between their endpoints s0,s1s_0,s_1. We give a self-contained account that builds on earlier work but emphasises applications to quantum computing as surface code theory, including gates on D(S3)D(S_3). We show how the theory reduces to a simpler theory for toric codes in the case of D(Zn)CZn2D( \Bbb Z_n)\cong \Bbb C\Bbb Z_n^2, including toric ribbon operators and their braiding. In the other direction, we show how our constructions generalise to D(H)D(H) models based on a finite-dimensional Hopf algebra HH, including site actions of D(H)D(H) and partial results on ribbon equivariance even when the Hopf algebra is not semisimple.

Keywords

Cite

@article{arxiv.2107.04411,
  title  = {Quantum double aspects of surface code models},
  author = {Alexander Cowtan and Shahn Majid},
  journal= {arXiv preprint arXiv:2107.04411},
  year   = {2022}
}

Comments

54 pages, many figures both pdf and tkz

R2 v1 2026-06-24T04:02:27.510Z