Abstract
Quantum error correction provides a path to large-scale quantum computers, but is built on challenging assumptions about the characteristics of the underlying errors. In particular, the mathematical assumption of statistically independent errors in quantum logic operations is at odds with realistic environments where error sources may exhibit strong temporal and spatial correlations. We present experiments using trapped ions to demonstrate that the use of dynamically corrected gates (DCGs), generally considered for the reduction of error magnitudes, can also suppress error correlations in space and time throughout quantum circuits. We present a first-principles analysis of the manifestation of error correlations in randomized benchmarking, and validate this model through experiments performed using engineered errors. We find that standard DCGs can reduce error correlations by $\sim50\times$, while increasing the magnitude of uncorrelated errors by a factor scaling linearly with the extended DCG duration compared to a primitive gate. We then demonstrate that the correlation characteristics of intrinsic errors in our system are modified by use of DCGs, consistent with a picture in which DCGs whiten the effective error spectrum induced by external noise.
Highlights
Suppressing and correcting errors in quantum circuits is a critical challenge driving a substantial fraction of research in the quantum information science community
We present experiments using trapped ions to demonstrate that the use of dynamically corrected gates (DCGs), generally considered for the reduction of error magnitudes, can suppress error correlations in space and time throughout quantum circuits
We find that standard DCGs can reduce error correlations by ∼50× while increasing the magnitude of uncorrelated errors by a factor scaling linearly with the extended DCG duration compared to a primitive gate
Summary
Suppressing and correcting errors in quantum circuits is a critical challenge driving a substantial fraction of research in the quantum information science community. These efforts build on quantum error correction (QEC) and the theory of fault tolerance [1,2,3,4,5,6] as fundamental developments that support the concept of large-scale quantum computation [7,8,9] In combination, these theoretical constructs suggest that so long as the probability of error in each physical quantum information carrier can be reduced below a threshold value, a properly executed QEC protocol can detect and suppress logical errors to arbitrarily low levels, and enable arbitrarily large computations. We demonstrate that using DCGs in sequence construction reduces spatial error correlations between qubits, through simultaneous randomized benchmarking on five trapped ion qubits These results provide direct and strong evidence that the use of dynamically protected physical qubit operations in a layered architecture for quantum computing [29] can facilitate the successful application of existing QEC theory with only minimal revision on the path to fault-tolerant quantum computation
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