Integrated Control Addressing Circuits for a Surface Code Quantum Computer in Silicon

Proceedings of the 17th ACM International Symposium on Nanoscale Architectures Pub Date : 2022-12-07 DOI:10.1145/3565478.3572541

Rubaya Absar, Zach D. Merino, H. Elgabra, Xuesong Chen, J. Baugh, Lan Wei

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Abstract

Quantum computers require a coordinated operation on a large number of quantum bits (qubits), presenting considerable obstacles such as system integration on a large scale, individual qubits control with precision, and significant error correction overhead. Silicon (Si) quantum dot (QD) spin qubits paired with CMOS control circuits promise a scalable solution due to its potential for large-scale integration utilizing well-established semiconductor technologies. This paper proposes a control addressing scheme for QD spin qubits operating on a node network architecture. Compared to the typical 2-dimensional array architecture, this approach considerably lowers the area constraint for control signal routing. Scalable circuits are designed to route the control signals for local and global operations of a surface code quantum error correction through the modular design of tiered switches controlled by demultiplexers. The proposed method is a critical step toward implementing scalable solid-state quantum processors.

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硅表面码量子计算机的集成控制寻址电路

量子计算机需要在大量量子比特(量子位)上进行协调操作，这存在相当大的障碍，例如大规模的系统集成，精确控制单个量子位，以及显着的纠错开销。硅(Si)量子点(QD)自旋量子比特与CMOS控制电路配对，由于其利用成熟的半导体技术进行大规模集成的潜力，有望提供可扩展的解决方案。提出了一种运行在节点网络结构上的量子点自旋量子比特的控制寻址方案。与典型的二维阵列结构相比，这种方法大大降低了控制信号路由的面积约束。可扩展电路设计用于路由控制信号，通过由解复用器控制的分层开关的模块化设计，用于表面代码量子纠错的本地和全局操作。该方法是实现可扩展固态量子处理器的关键一步。

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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Proceedings of the 17th ACM International Symposium on Nanoscale Architectures

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