Mitigating the Effects of Au-Al Intermetallic Compounds Due to High-Temperature Processing of Surface-Electrode Ion Traps

IF 2.3 3区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Components, Packaging and Manufacturing Technology Pub Date : 2024-06-24 DOI:10.1109/TCPMT.2024.3418648

Raymond A. Haltli;Eric Ou;Christopher D. Nordquist;Susan M. Clark;Melissa C. Revelle

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Abstract

Stringent physical requirements need to be met for the high-performing surface-electrode ion traps used in quantum computing and timekeeping. In particular, these traps must survive a high-temperature environment for vacuum chamber preparation and support high RF voltage on closely spaced electrodes. Due to the use of gold wire bonds on aluminum pads, intermetallic growth can lead to wire bond failure via breakage or high resistance, limiting the lifetime of a trap assembly to a single multiday bake at

$200~^{\circ }$

C. Using traditional thick metal stacks to prevent intermetallic growth, however, can result in trap failure due to RF breakdown events. Through high-temperature experiments, we conclude that an ideal metal stack for ion traps is Ti/Pt/Au (20/100/250 nm), which allows for a cumulative bakeable time of roughly 86 days without compromising the trap voltage performance. This increase in the bakeable lifetime of ion traps will remove the need to discard otherwise functional ion traps when vacuum hardware is upgraded, which will greatly benefit ion trap experiments.

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减轻表面电极离子捕集器高温处理过程中产生的金-铝金属间化合物的影响

用于量子计算和计时的高性能表面电极离子阱需要满足严格的物理要求。特别是，这些阱必须能在真空室制备的高温环境中生存，并能在紧密间隔的电极上支持高射频电压。由于在铝垫上使用金丝键，金属间的生长会导致金丝键因断裂或高电阻而失效，从而将阱组件的使用寿命限制在 200~^\{circ }$ C 的单次多日烘烤。通过高温实验，我们得出结论，离子阱的理想金属堆栈是 Ti/Pt/Au (20/100/250 nm)，它可以实现大约 86 天的累计可烘烤时间，而不会影响阱电压性能。离子阱可烘烤寿命的延长将使真空硬件升级时不再需要丢弃功能正常的离子阱，这将大大有利于离子阱实验。

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来源期刊

IEEE Transactions on Components, Packaging and Manufacturing Technology ENGINEERING, MANUFACTURING-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

4.70

自引率

13.60%

发文量

203

审稿时长

3 months

期刊介绍： IEEE Transactions on Components, Packaging, and Manufacturing Technology publishes research and application articles on modeling, design, building blocks, technical infrastructure, and analysis underpinning electronic, photonic and MEMS packaging, in addition to new developments in passive components, electrical contacts and connectors, thermal management, and device reliability; as well as the manufacture of electronics parts and assemblies, with broad coverage of design, factory modeling, assembly methods, quality, product robustness, and design-for-environment.