采用 22 纳米 FDSOI CMOS 的硅自旋质子控制和读出电路

arXiv - PHYS - Quantum Physics Pub Date : 2024-09-12 DOI:arxiv-2409.08182

Raffaele R. Severino, Michele Spasaro, Domenico Zito

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引用次数: 0

摘要

本文研究了用于控制和读出电子/空穴自旋量子比特的微波和毫米波集成电路的实现，电子/空穴自旋量子比特是未来新兴量子计算技术的基本构件。特别是，本文总结了电子/空穴自旋量子比特最相关的读出和控制技术，探讨了可行性，并报告了两个模块的初步仿真结果：跨阻抗放大器（TIA）和脉冲发生器（PG）。跨阻抗放大器在 18 GHz 的 -3dB 带宽内具有 108.5 dBOhm 的跨阻抗增益，10 GHz 时的输入参考噪声电流谱密度为 0.89 pA/根（Hz）。PG 可提供最小持续时间为 20 ps 的毫米波正弦脉冲。

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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Silicon Spin Qubit Control and Readout Circuits in 22nm FDSOI CMOS

This paper investigates the implementation of microwave and mm-wave integrated circuits for control and readout of electron/hole spin qubits, as elementary building blocks for future emerging quantum computing technologies. In particular, it summarizes the most relevant readout and control techniques of electron/hole spin qubits, addresses the feasibility and reports some preliminary simulation results of two blocks: transimpedance amplifier (TIA) and pulse generator (PG). The TIA exhibits a transimpedance gain of 108.5 dB Ohm over a -3dB bandwidth of 18 GHz, with input-referred noise current spectral density of 0.89 pA/root(Hz) at 10 GHz. The PG provides a mm-wave sinusoidal pulse with a minimum duration time of 20 ps.

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arXiv - PHYS - Quantum Physics

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