Tailoring fusion-based error correction for high thresholds to biased fusion failures
Abstract
We introduce fault-tolerant (FT) architectures for error correction with the XZZX cluster state based on performing measurements of two-qubit Pauli operators Z Z and X X, or fusions, on a collection of few-body entangled resource states. Our construction is tailored to be effective against noise that predominantly causes faulty X X measurements during fusions. This feature offers practical advantage in linear optical quantum computing with dual-rail photonic qubits, where failed fusions only erase X X measurement outcomes. By applying our construction to this platform, we find a record high FT threshold to fusion failures exceeding 25\% in the experimentally relevant regime of non-zero loss rate per photon, considerably simplifying hardware requirements.
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