Individually Addressed Quantum Gate Interactions Using Dynamical Decoupling

PRX Quantum Pub Date : 2024-08-01 DOI:10.1103/prxquantum.5.030321

M.C. Smith, A.D. Leu, M.F. Gely, D.M. Lucas

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Abstract

A leading approach to implementing small-scale quantum computers has been to use laser beams, focused to micron spot sizes, to address and entangle trapped ions in a linear crystal. Here we propose a method to implement individually addressed entangling gate interactions, but driven by microwave fields, with a spatial resolution of a few microns, corresponding to

10^{- 5}

microwave wavelengths. We experimentally demonstrate the ability to suppress the effect of the state-dependent force using a single ion, and find the required interaction introduces

3.7 (4) \times 10^{- 4}

error per emulated gate in a single-qubit benchmarking sequence. We model the scheme for a 17-qubit ion crystal, and find that any pair of ions should be addressable with an average crosstalk error of approximately

10^{- 5}

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利用动态解耦单独处理量子门相互作用

实现小规模量子计算机的一种主要方法是使用聚焦到微米光斑大小的激光束来处理和纠缠线性晶体中的被困离子。在这里，我们提出了一种实现单独寻址纠缠门相互作用的方法，但由微波场驱动，空间分辨率为几微米，相当于 10-5 微波波长。我们通过实验证明了利用单个离子抑制随状态变化的作用力的能力，并发现在单量子比特基准序列中，所需的相互作用会给每个仿真门带来 3.7(4)×10-4 的误差。我们为一个 17 量子位离子晶体建立了该方案的模型，并发现任何一对离子都可以寻址，平均串扰误差约为 10-5。

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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