English

Ultrahigh Error Threshold for Surface Codes with Biased Noise

Quantum Physics 2018-02-07 v3

Abstract

We show that a simple modification of the surface code can exhibit an enormous gain in the error correction threshold for a noise model in which Pauli Z errors occur more frequently than X or Y errors. Such biased noise, where dephasing dominates, is ubiquitous in many quantum architectures. In the limit of pure dephasing noise we find a threshold of 43.7(1)% using a tensor network decoder proposed by Bravyi, Suchara and Vargo. The threshold remains surprisingly large in the regime of realistic noise bias ratios, for example 28.2(2)% at a bias of 10. The performance is in fact at or near the hashing bound for all values of the bias. The modified surface code still uses only weight-4 stabilizers on a square lattice, but merely requires measuring products of Y instead of Z around the faces, as this doubles the number of useful syndrome bits associated with the dominant Z errors. Our results demonstrate that large efficiency gains can be found by appropriately tailoring codes and decoders to realistic noise models, even under the locality constraints of topological codes.

Keywords

Cite

@article{arxiv.1708.08474,
  title  = {Ultrahigh Error Threshold for Surface Codes with Biased Noise},
  author = {David K. Tuckett and Stephen D. Bartlett and Steven T. Flammia},
  journal= {arXiv preprint arXiv:1708.08474},
  year   = {2018}
}

Comments

6 pages, 5 figures, comments welcome; v2 includes minor improvements to the numerical results, additional references, and an extended discussion; v3 published version (incorporating supplementary material into main body of paper)

R2 v1 2026-06-22T21:25:34.102Z