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Showing 1–4 of 4 results
Advanced filters: Author: Steven T. Flammia Clear advanced filters

  • The surface code is a keystone in quantum error correction, but it does not generally perform well against structured noise and suffers from large overheads. Here, the authors demonstrate that a variant of it has better performance and requires fewer resources, without additional hardware demands.

    • J. Pablo Bonilla Ataides
    • David K. Tuckett
    • Benjamin J. Brown
    ResearchOpen Access
    Nature Communications
    Volume: 12, P: 1-12

  • Direct quantum state tomography—deducing the state of a system from measurements—is mostly unfeasible due to the exponential scaling of measurement number with system size. The authors present two new schemes, which scale linearly in this respect, and can be applied to a wide range of quantum states.

    • Marcus Cramer
    • Martin B. Plenio
    • Yi-Kai Liu
    Research
    Nature Communications
    Volume: 1, P: 1-7

  • Randomized measurements provide a feasible procedure for probing properties of many-body quantum states realized in today’s quantum simulators and quantum computers. This Review covers implementation, classical post-processing and theoretical performance guarantees of randomized measurement protocols, surveying their many applications and discussing current challenges.

    • Andreas Elben
    • Steven T. Flammia
    • Peter Zoller
    Reviews
    Nature Reviews Physics
    Volume: 5, P: 9-24

  • A protocol for the reliable, efficient and precise characterization of quantum noise is reported and implemented in an architecture consisting of 14 superconducting qubits. Correlated noise within arbitrary sets of qubits can be easily detected.

    • Robin Harper
    • Steven T. Flammia
    • Joel J. Wallman
    Research
    Nature Physics
    Volume: 16, P: 1184-1188