用于千兆赫低温工作的量子位控制器和观测器电路

S. Ramesh Ekanayake, T. Lehmann, A. Dzurak, R. G. Clark
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引用次数: 9

摘要

量子比特(量子位)控制和读出需要控制器-量子位-观测器系统来快速控制信号的产生和注入到量子位门,并观察它们的最终状态投影。传统上,对于固态量子比特来说,这是通过在300k下产生控制信号,并沿着从300k到sub-K(通常小于500mk)的非常长的同轴电缆传输,然后沿着类似长度的电缆读取电荷接近传感器(如单电子晶体管)的响应来实现的。我们的方法是使用商业铸造加工的蓝宝石上硅(SOS) RFCMOS技术制造经典控制器和观测器电路,以便在低温(4.2 K, 1k或低于K)下操作。我们已经演示了在4.2 K和sub-K下运行的SOS-CMOS NFET和PFET器件,显示出与其300 K特性的偏差,但通过进一步的实验,这些被证明对控制电路功能的影响最小。利用这些结果,我们制造并演示了一种低功耗的概念验证型SOS-CMOS控制器电路(单稳态100 ps电压脉冲发生器),可以在稀释冰箱的亚k温度下工作。我们简要地讨论了实验和概念方案,利用这些方案我们可以开发低温和低温的量子比特控制系统。这些低温实验也证明了商用SOS RF-CMOS技术在其他低温低功耗应用中是可行的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Quantum bit controller and observer circuits in SOS-CMOS technology for gigahertz low-temperature operation
Quantum bit (qubit) control and readout requires controller-qubit-observer systems for rapid control signal generation and injection to the qubit gates, and observation of their final state projections. Conventionally, for solid-state qubits, this is achieved by generating the control signal at 300 K and transmitting it along very long coaxial cables that span from 300 K to sub-K (typically les 500 mK), then reading out the response from charge proximity sensors such as single-electron transistors along similar lengths of cable. Our approach is to fabricate the classical controller and observer circuits using a commercial foundry processed silicon-on-sapphire (SOS) RFCMOS technology for operation at low temperatures (either at 4.2 K, 1 K, or sub-K). We have demonstrated SOS-CMOS NFET and PFET device operation at 4.2 K, and sub-K that showed deviations from their 300 K characteristics, but with further experiments these were shown to have minimal effects on control circuit function. Using these results, we have fabricated and demonstrated a low-power proof-of-concept SOS-CMOS controller circuit (monostable 100 ps voltage-pulse generator) that can operate at sub-K temperatures in a dilution refrigerator. We briefly discuss experimental and conceptual schemes with which we can develop qubit control systems for cryogenic and lower temperatures. These low temperature experiments also demonstrate that commercial SOS RF-CMOS technology can be feasible for other low temperature and low power applications.
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