Gate modulation of the hole singlet-triplet qubit frequency in germanium

IF 6.6 1区物理与天体物理 Q1 PHYSICS, APPLIED

npj Quantum Information Pub Date : 2025-01-29 DOI:10.1038/s41534-024-00953-3

John Rooney, Zhentao Luo, Lucas E. A. Stehouwer, Giordano Scappucci, Menno Veldhorst, Hong-Wen Jiang

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Abstract

Spin qubits in germanium gate-defined quantum dots have made considerable progress within the last few years, partially due to their strong spin-orbit coupling and site-dependent g-tensors. While this characteristic of the g-factors removes the need for micromagnets and allows for the possibility of all-electric qubit control, relying on these g-tensors necessitates the need to understand their sensitivity to the confinement potential that defines the quantum dots. Here, we demonstrate a S − T_ qubit whose frequency is a strong function of the voltage applied to the barrier gate shared by the quantum dots. We find a g-factor that can be approximately increased by an order of magnitude adjusting the barrier gate voltage only by 12 mV. We show how this strong dependence could potentially be attributed to the dots moving through a variable strain environment in our device. This work not only reinforces previous findings that site-dependent g-tensors in germanium can be utilized for qubit manipulation, but reveals the sensitivity and tunability these g-tensors have to the electrostatic confinement of the quantum dot.

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锗中空穴单重态-三重态量子比特频率的门调制

锗门定义量子点中的自旋量子位在过去几年中取得了相当大的进展，部分原因是它们具有强的自旋轨道耦合和位点依赖的g张量。虽然g因子的这种特性消除了对微磁体的需求，并允许全电量子比特控制的可能性，但依靠这些g张量需要了解它们对定义量子点的限制势的敏感性。在这里，我们展示了一个S - T_量子比特，其频率是施加在量子点共享的势垒门上的电压的强函数。我们发现一个g因子可以大约增加一个数量级，调整栅极电压仅为12 mV。我们展示了这种强烈的依赖性是如何潜在地归因于在我们的设备中通过可变应变环境移动的点。这项工作不仅强化了先前的发现，即锗中依赖于位的g张量可以用于量子比特操作，而且揭示了这些g张量对量子点静电约束的敏感性和可调性。

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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来源期刊

npj Quantum Information Computer Science-Computer Science (miscellaneous)

CiteScore

13.70

自引率

3.90%

发文量

130

审稿时长

29 weeks

期刊介绍： The scope of npj Quantum Information spans across all relevant disciplines, fields, approaches and levels and so considers outstanding work ranging from fundamental research to applications and technologies.