Related papers: Error per single-qubit gate below $10^{-4}$ in a superconducting qubit

Error per single-qubit gate below $10^{-4}$ in a superconducting qubit

URL: http://arxiv.org/abs/2302.08690v1
Date: Fri, 17 Feb 2023 04:43:38 GMT
Title: Error per single-qubit gate below $10^{-4}$ in a superconducting qubit
Authors: Zhiyuan Li, Pei Liu, Peng Zhao, Zhenyu Mi, Huikai Xu, Xuehui Liang, Tang Su, Weijie Sun, Guangming Xue, Jing-Ning Zhang, Weiyang Liu, Yirong Jin, and Haifeng Yu
Abstract summary: We fabric a transmon qubit with long coherence times and demonstrate single-qubit gates with the average gate error below $10-4$. The demonstration extends the upper limit that the average fidelity of single-qubit gates can reach in a transmon-qubit system.
Score: 14.29906536440178
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Implementing arbitrary single-qubit gates with near perfect fidelity is among the most fundamental requirements in gate-based quantum information processing. In this work, we fabric a transmon qubit with long coherence times and demonstrate single-qubit gates with the average gate error below $10^{-4}$, i.e. $(7.42\pm0.04)\times10^{-5}$ by randomized benchmarking (RB). To understand the error sources, we experimentally obtain an error budget, consisting of the decoherence errors lower bounded by $(4.62\pm0.04)\times10^{-5}$ and the leakage rate per gate of $(1.16\pm0.04)\times10^{-5}$. Moreover, we reconstruct the process matrices for the single-qubit gates by the gate set tomography (GST), with which we simulate RB sequences and obtain single-qubit fedlities consistent with experimental results. We also observe non-Markovian behavior in the experiment of long-sequence GST, which may provide guidance for further calibration. The demonstration extends the upper limit that the average fidelity of single-qubit gates can reach in a transmon-qubit system, and thus can be an essential step towards practical and reliable quantum computation in the near future.

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