Stable and low loss oxide layer on α-Ta (110) film for superconducting qubits

Zengqian Ding, Boyi Zhou, Tao Wang, Lina Yang, Yanfu Wu, Xiao Cai, Kanglin Xiong, Jiagui Feng
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Abstract

The presence of amorphous oxide layers can significantly affect the coherent time of superconducting qubits due to their high dielectric loss. Typically, the surface oxides of superconductor films exhibit lossy and unstable behavior when exposed to air. To increase the coherence time, it is essential for qubits to have stable and low dielectric loss oxides, either as barrier or passivation layers. In this study, we highlight the robust and stable nature of an amorphous tantalum oxide layer formed on α-Ta (110) film by employing chemical and structural analyses. Such kind of oxide layer forms in a self-limiting process on the surface of α-Ta (110) film in piranha solution, yielding stable thickness and steady chemical composition. Quarter-wavelength coplanar waveguide resonators are made to study the loss of this oxide. One resonator has a Qi of 3.0 × 106 in the single photon region. The Qi of most devices are higher than 2.0 × 106. Moreover, most of them are still over 1 × 106 even after exposed to air for months. Based on these findings, we propose an all-tantalum superconducting qubit utilizing such oxide as passivation layers, which possess low dielectric loss and improved stability.
α-Ta(110)薄膜上用于超导量子比特的稳定低损耗氧化物层
无定形氧化物层的存在会严重影响超导量子比特的相干时间,因为它们具有很高的介电损耗。通常情况下,超导体薄膜的表面氧化物暴露在空气中会出现损耗和不稳定现象。为了增加相干时间,量子比特必须具有稳定且介电损耗低的氧化物,无论是作为阻挡层还是钝化层。在本研究中,我们通过化学和结构分析,强调了在α-Ta(110)薄膜上形成的非晶态钽氧化物层的坚固性和稳定性。这种氧化层是在食人鱼溶液中的α-Ta(110)薄膜表面通过自限制过程形成的,具有稳定的厚度和化学成分。为了研究这种氧化物的损耗,我们制作了四分之一波长的共面波导谐振器。其中一个谐振器在单光子区域的 Qi 值为 3.0 × 106。大多数器件的齐次值都高于 2.0 × 106。此外,即使暴露在空气中数月,大多数器件的气数仍超过 1 × 106。基于这些发现,我们提出了一种利用这种氧化物作为钝化层的全钽超导量子比特,它具有较低的介电损耗和更高的稳定性。
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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