Spin-qubit control with a milli-kelvin CMOS chip.

IF 50.5 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Nature Pub Date : 2025-06-25 DOI:10.1038/s41586-025-09157-x

Samuel K Bartee,Will Gilbert,Kun Zuo,Kushal Das,Tuomo Tanttu,Chih Hwan Yang,Nard Dumoulin Stuyck,Sebastian J Pauka,Rocky Y Su,Wee Han Lim,Santiago Serrano,Christopher C Escott,Fay E Hudson,Kohei M Itoh,Arne Laucht,Andrew S Dzurak,David J Reilly

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引用次数: 0

Abstract

A key virtue of spin qubits is their sub-micron footprint, enabling a single silicon chip to host the millions of qubits required to execute useful quantum algorithms with error correction1-3. However, with each physical qubit needing multiple control lines, a fundamental barrier to scale is the extreme density of connections that bridge quantum devices to their external control and readout hardware4-6. A promising solution is to co-locate the control system proximal to the qubit platform at milli-kelvin temperatures, wired up by miniaturized interconnects7-10. Even so, heat and crosstalk from closely integrated control have the potential to degrade qubit performance, particularly for two-qubit entangling gates based on exchange coupling that are sensitive to electrical noise11,12. Here we benchmark silicon metal-oxide-semiconductor (MOS)-style electron spin qubits controlled by heterogeneously integrated cryo-complementary metal-oxide-semiconductor (cryo-CMOS) circuits with a power density sufficiently low to enable scale-up. Demonstrating that cryo-CMOS can efficiently perform universal logic operations for spin qubits, we go on to show that milli-kelvin control has little impact on the performance of single- and two-qubit gates. Given the complexity of our sub-kelvin CMOS platform, with about 100,000 transistors, these results open the prospect of scalable control based on the tight packaging of spin qubits with a 'chiplet-style' control architecture.

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用毫开尔文CMOS芯片控制自旋量子位。

自旋量子比特的一个关键优点是它们的亚微米尺寸，使单个硅芯片能够承载数百万个量子比特，以执行具有纠错功能的有用量子算法1-3。然而，由于每个物理量子位需要多条控制线，扩展的一个基本障碍是连接量子设备与其外部控制和读出硬件的极端密度。一个有希望的解决方案是在毫开尔文温度下将控制系统与量子位平台共同定位，并通过微型互连连接起来7-10。即便如此，来自紧密集成控制的热量和串扰仍有可能降低量子比特的性能，特别是对于基于对电噪声敏感的交换耦合的双量子比特纠缠门11,12。在这里，我们对硅金属氧化物半导体（MOS）式电子自旋量子比特进行基准测试，该量子比特由异质集成的低温互补金属氧化物半导体（cryo-CMOS）电路控制，其功率密度足够低，可以进行放大。为了证明cro - cmos可以有效地执行自旋量子比特的通用逻辑运算，我们继续证明毫开尔文控制对单量子比特和双量子比特门的性能几乎没有影响。考虑到我们的亚开尔文CMOS平台的复杂性，大约有10万个晶体管，这些结果打开了基于自旋量子比特与“芯片式”控制架构紧密封装的可扩展控制的前景。

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

Nature 综合性期刊-综合性期刊

CiteScore

90.00

自引率

1.20%

发文量

3652

审稿时长

3 months

期刊介绍： Nature is a prestigious international journal that publishes peer-reviewed research in various scientific and technological fields. The selection of articles is based on criteria such as originality, importance, interdisciplinary relevance, timeliness, accessibility, elegance, and surprising conclusions. In addition to showcasing significant scientific advances, Nature delivers rapid, authoritative, insightful news, and interpretation of current and upcoming trends impacting science, scientists, and the broader public. The journal serves a dual purpose: firstly, to promptly share noteworthy scientific advances and foster discussions among scientists, and secondly, to ensure the swift dissemination of scientific results globally, emphasizing their significance for knowledge, culture, and daily life.