22nm量子SoC中静电控制量子点的低温控制器

Robert Bogdan Staszewski;Ali Esmailiyan;Hongying Wang;Eugene Koskin;Panagiotis Giounanlis;Xutong Wu;Anna Koziol;Andrii Sokolov;Imran Bashir;Mike Asker;Dirk Leipold;Reza Nikandish;Teerachot Siriburanon;Elena Blokhina
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引用次数: 0

摘要

我们提出了一种用于静电控制量子点(QDs)的完全集成低温控制器,该控制器在商业22nm完全耗尽的绝缘体上硅CMOS工艺中实现,并在量子区中操作。量子点是在晶体管的局部阱区中实现的,这些阱区由施加到栅极端子的电压控制的隧道势垒分隔。QD阵列(QDA)与每个量子实验单元内的控制电路共同定位,总共28个这样的单元包括该片上系统(SoC)。QDA结构由小型电容式数模转换器(CDACs)控制,量子态由单电子探测器测量。SoC在3.4K的低温下工作。每个QDA的占用面积为0.7美元乘以0.4μ\text{m}^2美元,而每个QD仅占用20美元乘以80μ\text{nm}^2$。这些电路的低功率和小型化区域是将大型量子核心与数百万量子点集成的重要一步,这是实用量子计算机所需的。CDAC的性能和功能在环回模式中得到验证,检测器感测CDAC迫使电子从量子点接触(QPC)节点隧穿到量子结构中。QDA内部注入电荷的位置旨在通过CDAC代码和可编程脉冲宽度来控制。量子效应通过电荷注入和量化到由三个耦合量子点组成的量子点中的实验表征来显示。电荷可以转移到QD并在QPC处感测,并且该过程由相关电压和CDAC控制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cryogenic Controller for Electrostatically Controlled Quantum Dots in 22-nm Quantum SoC
We present a fully integrated cryogenic controller for electrostatically controlled quantum dots (QDs) implemented in a commercial 22-nm fully depleted silicon-on-insulator CMOS process and operating in a quantum regime. The QDs are realized in local well areas of transistors separated by tunnel barriers controlled by voltages applied to gate terminals. The QD arrays (QDA) are co-located with the control circuitry inside each quantum experiment cell, with a total of 28 of such cells comprising this system-on-chip (SoC). The QDA structure is controlled by small capacitive digital-to-analog converters (CDACs) and its quantum state is measured by a single-electron detector. The SoC operates at a cryogenic temperature of 3.4K. The occupied area of each QDA is $0.7 \times 0.4\mu \text{m}^2$ , while each QD occupies only $20 \times 80 \text{nm}^2$ . The low power and miniaturized area of these circuits are an important step on the way for integration of a large quantum core with millions of QDs, required for practical quantum computers. The performance and functionality of the CDAC are validated in a loop-back mode with the detector sensing the CDAC-compelled electron tunneling from the quantum point contact (QPC) node into the quantum structure. The position of the injected charge inside the QDA is intended to be controlled through the CDAC codes and programmable pulse width. Quantum effects are shown by an experimental characterization of charge injection and quantization into the QDA consisting of three coupled QDs. The charge can be transferred to a QD and sensed at the QPC, and this process is controlled by the relevant voltages and CDACs.
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