We introduce fault-tolerant (FT) architectures for error correction with the
XZZX cluster state based on performing measurements of two-qubit Pauli
operators ZβZ and XβX, or fusions, on a collection of
few-body entangled resource states. Our construction is tailored to be
effective against noise that predominantly causes faulty XβX
measurements during fusions. This feature offers practical advantage in linear
optical quantum computing with dual-rail photonic qubits, where failed fusions
only erase XβX 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.Comment: 7+6 pages, 4+6 figures, comments welcom