Enhancing the Clique Local Decoder to Correct Length-2 Space Errors in the Surface Code

Abstract

The growing demand for fault-tolerant quantum computing drives the need for efficient, scalable Quantum Error Correction (QEC) strategies. Conventional decoders designed for worst-case error scenarios incur significant overhead, prompting the development of local decoders, that leverage the sparse and often trivial nature of many quantum errors, to support the conventional decoders. The previously proposed Clique decoder addresses this by handling isolated, length-1 space and time errors within the cryogenic environment with minimal hardware costs, thereby mitigating I/O bandwidth constraints between cryogenic quantum systems and room-temperature processors. Building on this foundation, we propose CliqueL2 that extends the Clique-based approach by relaxing some original constraints and incorporating additional low-cost logic to also correct length-2 error chains in space, which become non-trivial occurrences at higher physical error rates and code distances. This enhanced capability not only further reduces out-of-the-fridge data transmission but also adapts more effectively to clustered errors observed under a variety of noise models. Specifically, under data-qubit-only errors and uniformly random noise, CliqueL2 achieves up to 8.95x decoding bandwidth reduction over the original Clique (or CliqueL1) decoder, especially beneficial at higher code distances. When clustered errors and longer error chains are more likely to occur, CliqueL2 achieves up to 18.3x decoding bandwidth reduction over CliqueL1, achieving substantial benefits across a wide range of physical qubit error rates.