Demonstration of Fault-Tolerant Steane Quantum Error Correction

PRX Quantum Pub Date : 2024-08-07 DOI:10.1103/prxquantum.5.030326

Lukas Postler, Friederike Butt, Ivan Pogorelov, Christian D. Marciniak, Sascha Heußen, Rainer Blatt, Philipp Schindler, Manuel Rispler, Markus Müller, Thomas Monz

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Abstract

Encoding information redundantly using quantum error-correcting (QEC) codes allows one to overcome the inherent sensitivity to noise in quantum computers to ultimately achieve large-scale quantum computation. The Steane QEC method involves preparing an auxiliary logical qubit of the same QEC code as used for the data register. The data and auxiliary registers are then coupled with a logical controlled-not (cnot) gate, enabling a measurement of the auxiliary register to reveal the error syndrome. This study presents the implementation of multiple rounds of fault-tolerant (FT) Steane QEC on a trapped-ion quantum computer. Various QEC codes are employed and the results are compared to a previous experimental approach utilizing flag qubits. Our experimental findings show improved logical fidelities for Steane QEC and accompanying numerical simulations indicate an even larger performance advantage for quantum processors limited by entangling-gate errors. This establishes experimental Steane QEC as a competitive paradigm for FT quantum computing.

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容错 Steane 量子纠错演示

使用量子纠错（QEC）代码对信息进行冗余编码，可以克服量子计算机对噪声的固有敏感性，最终实现大规模量子计算。Steane QEC 方法包括准备一个与数据寄存器所用 QEC 代码相同的辅助逻辑量子比特。然后将数据寄存器和辅助寄存器与逻辑受控-非（cnot）门耦合，通过测量辅助寄存器来揭示错误综合征。本研究介绍了在困离子量子计算机上实施多轮容错 Steane QEC 的情况。我们采用了各种 QEC 代码，并将结果与之前利用标志量子位的实验方法进行了比较。我们的实验结果表明，Steane QEC 的逻辑保真度得到了提高，同时进行的数值模拟表明，对于受纠缠栅极误差限制的量子处理器来说，Steane QEC 的性能优势甚至更大。这确立了实验性 Steane QEC 作为 FT 量子计算的竞争范例的地位。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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PRX Quantum

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