Traveling-wave parametric amplifier–induced qubit dephasing: analysis and mitigation

Chip Pub Date : 2023-12-01 DOI:10.1016/j.chip.2023.100067

Yingshan Zhang , Huikai Xu , Yu Song , Yuqun Xu , Shuang Yang , Ziyue Hua , Shoukuan Zhao , Weiyang Liu , Guangming Xue , Yirong Jin , Haifeng Yu

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Abstract

The mitigation of dephasing poses a significant challenge to improving the performance of error-prone superconducting quantum computing systems. Here, the dephasing of a transmon qubit in a dispersive readout regime was investigated by adopting a Josephson traveling-wave parametric amplifier as the preamplifier. Our findings reveal that the potent pump leakage from the preamplifier may lead to severe dephasing. This could be attributed to a mixture of measurement-induced dephasing, ac Stark effect, and heating. It is showed that pulse-mode readout is a promising measurement scheme to mitigate qubit dephasing while minimizing the need for bulky circulators. Our work provides key insights into mitigating decoherence from microwave-pumped preamplifiers, which will be critical for advancing large-scale quantum computers.

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行波参量放大器诱发的量子比特退相：分析与缓解

要提高易出错的超导量子计算系统的性能，减少退相是一项重大挑战。在这里，我们采用约瑟夫森行波参量放大器作为前置放大器，研究了在色散读出机制下跨mon量子比特的退相现象。我们的研究结果表明，前置放大器的强泵泄漏可能会导致严重的去相。这可能是测量诱导的失相、交流斯塔克效应和加热的混合结果。研究表明，脉冲模式读出是一种很有前途的测量方案，可减轻量子比特失相，同时最大限度地减少对笨重的循环器的需求。我们的研究为减轻微波泵浦前置放大器的退相干现象提供了重要见解，这对推动大规模量子计算机的发展至关重要。

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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Chip

CiteScore

2.80

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0.00%

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