Solid state qubits: how learning from CMOS fabrication can speed-up progress in Quantum Computing

2021 Symposium on VLSI Circuits Pub Date : 2021-06-13 DOI:10.23919/VLSICircuits52068.2021.9492397

I. Radu, Roy Li, A. Potočnik, T. Ivanov, D. Wan, S. Kubicek, N. D. Stuyck, J. Verjauw, J. Jussot, Y. Canvel, C. Godfrin, M. Mongillo, R. Acharya, A. Elsayed, M. Shehata, X. Piao, A. Pacco, L. Souriau, S. Couet, B. Chan, J. Craninckx, B. Parvais, A. Grill, S. Narasimhamoorthy, S. V. Winckel, S. Brebels, F. Mohiyaddin, G. Simion, B. Govoreanu

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Abstract

Building quantum computers requires not only a large number of qubits with high fidelity and low variability, but also a large amount of analog and digital components to drive the qubits. Larger arrays of solid-state qubits with high fidelity and low variability require improvements in fabrication processes and array layout design co-optimized with the underlying hardware technology. Here we outline progress on 300mm fabrication of qubit devices and on classical CMOS components to enable the quantum system. We describe work on superconducting qubits and spin qubits in Si, both types of devices fabricated on 300mm experimental platforms and discuss challenges related to variability. Massive electrical characterization is key over wide temperature range is key to enabling system upscaling for QC.

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固态量子比特:从CMOS制造中学习如何加速量子计算的进展

构建量子计算机不仅需要大量具有高保真度和低可变性的量子比特，还需要大量的模拟和数字元件来驱动量子比特。更大的具有高保真度和低可变性的固态量子比特阵列需要改进制造工艺和阵列布局设计，并与底层硬件技术协同优化。在这里，我们概述了300mm量子比特器件的制造和经典CMOS元件的进展，以实现量子系统。我们描述了在硅中超导量子比特和自旋量子比特的工作，这两种类型的设备都是在300mm实验平台上制造的，并讨论了与可变性相关的挑战。大规模的电气特性是关键，在宽温度范围内是关键，使QC系统升级。

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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2021 Symposium on VLSI Circuits

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