Universal quantum computation via scalable measurement-free error correction (2412.15187v2)

Abstract: We show that universal quantum computation can be made fault-tolerant in a scenario where the error-correction is implemented without mid-circuit measurements. To this end, we introduce a measurement-free deformation protocol of the Bacon-Shor code to realize a logical $\mathit{CCZ}$ gate, enabling a universal set of fault-tolerant operations. Independently, we demonstrate that certain stabilizer codes can be concatenated in a measurement-free way without having to rely on a universal logical gate set. This is achieved by means of the disposable Toffoli gadget, which realizes the feedback operation in a resource-efficient way. For the purpose of benchmarking the proposed protocols with circuit-level noise, we implement an efficient method to simulate non-Clifford circuits consisting of few Hadamard gates. In particular, our findings support that below-breakeven logical performance is achievable with a circuit-level error rate below $10^{-3}$. Altogether, the deformation protocol and the Toffoli gadget provide a blueprint for a fully fault-tolerant architecture without any feed-forward operation, which is particularly suited for state-of-the-art neutral-atom platforms.