Mitigation of interfacial dielectric loss in aluminum-on-silicon superconducting qubits

IF 6.6 1区物理与天体物理 Q1 PHYSICS, APPLIED

npj Quantum Information Pub Date : 2024-08-14 DOI:10.1038/s41534-024-00868-z

Janka Biznárová, Amr Osman, Emil Rehnman, Lert Chayanun, Christian Križan, Per Malmberg, Marcus Rommel, Christopher Warren, Per Delsing, August Yurgens, Jonas Bylander, Anita Fadavi Roudsari

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Abstract

We demonstrate aluminum-on-silicon planar transmon qubits with time-averaged T₁ energy relaxation times of up to 270 μs, corresponding to Q = 5 million, and a highest observed value of 501 μs. Through materials analysis techniques and numerical simulations we investigate the dominant source of energy loss, and devise and demonstrate a strategy toward its mitigation. Growing aluminum films thicker than 300 nm reduces the presence of oxide, a known host of defects, near the substrate-metal interface, as confirmed by time-of-flight secondary ion mass spectrometry. A loss analysis of coplanar waveguide resonators shows that this results in a reduction of dielectric loss due to two-level system defects. The correlation between the enhanced performance of our devices and the film thickness is due to the aluminum growth in columnar structures of parallel grain boundaries: transmission electron microscopy shows larger grains in the thicker film, and consequently fewer grain boundaries containing oxide near the substrate-metal interface.

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减轻铝硅超导量子比特的界面介电损耗

我们展示了铝硅平面跨文量子比特，其时间平均 T1 能量弛豫时间高达 270 μs，相当于 Q = 500 万，观测到的最高值为 501 μs。通过材料分析技术和数值模拟，我们研究了能量损耗的主要来源，并设计和展示了一种减少能量损耗的策略。通过飞行时间二次离子质谱法证实，生长厚度超过 300 nm 的铝膜可减少基底-金属界面附近氧化物的存在，而氧化物是已知的缺陷宿主。共面波导谐振器的损耗分析表明，这减少了两级系统缺陷造成的介质损耗。我们器件性能的提高与薄膜厚度之间的相关性是由于铝在平行晶界的柱状结构中生长：透射电子显微镜显示较厚薄膜中的晶粒较大，因此基底-金属界面附近含有氧化物的晶界较少。

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.