English

Recursive Clifford noise reduction

Quantum Physics 2025-12-01 v1

Abstract

Clifford noise reduction (CliNR) is a partial error correction scheme that reduces the logical error rate of Clifford circuits at the cost of a modest qubit and gate overhead. The CliNR implementation of an nn-qubit Clifford circuit of size ss achieves a vanishing logical error rate if snp20snp^2\rightarrow 0 where pp is the physical error rate. Here, we propose a recursive version of CliNR that can reduce errors on larger circuits with a relatively small gate overhead. When np0np \rightarrow 0, the logical error rate can be vanishingly small. This implementation requires (2log(sp)+3)n+1\left(2\left\lceil \log(sp)\right\rceil+3\right)n+1 qubits and at most 24s(sp)424 s \left\lceil(sp)^4\right\rceil gates. Using numerical simulations, we show that the recursive method can offer an advantage in a realistic near-term parameter regime. When circuit sizes are large enough, recursive CliNR can reach a lower logical error rate than the original CliNR with the same gate overhead. The results offer promise for reducing logical errors in large Clifford circuits with relatively small overheads.

Keywords

Cite

@article{arxiv.2511.22624,
  title  = {Recursive Clifford noise reduction},
  author = {Aharon Brodutch and Gregory Baimetov and Edwin Tham and Nicolas Delfosse},
  journal= {arXiv preprint arXiv:2511.22624},
  year   = {2025}
}
R2 v1 2026-07-01T07:58:21.755Z