A four-qubit germanium quantum processor

Hendrickx Nico W.; Lawrie William I. L.; Russ Maximilian; van Riggelen Floor; de Snoo Sander L.; Schouten Raymond N.; Sammak Amir; Scappucci Giordano; Veldhorst Menno

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A four-qubit germanium quantum processor

机译：四种Qubit锗量子处理器

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The prospect of building quantum circuits(1,2) using advanced semiconductor manufacturing makes quantum dots an attractive platform for quantum information processing(3,4). Extensive studies of various materials have led to demonstrations of two-qubit logic in gallium arsenide(5), silicon(6-12) and germanium(13). However, interconnecting larger numbers of qubits in semiconductor devices has remained a challenge. Here we demonstrate a four-qubit quantum processor based on hole spins in germanium quantum dots. Furthermore, we define the quantum dots in a two-by-two array and obtain controllable coupling along both directions. Qubit logic is implemented all-electrically and the exchange interaction can be pulsed to freely program one-qubit, two-qubit, three-qubit and four-qubit operations, resulting in a compact and highly connected circuit. We execute a quantum logic circuit that generates a four-qubit Greenberger-Horne-Zeilinger state and we obtain coherent evolution by incorporating dynamical decoupling. These results are a step towards quantum error correction and quantum simulation using quantum dots.

机译：建筑量子电路（1,2）的前景使用先进的半导体制造使得量子点成为量子信息处理的有吸引力平台（3,4）。对各种材料的广泛研究导致了砷化镓（5），硅（6-12）和锗（13）中的双量子比特逻辑的示范。然而，互连半导体器件中的更多数量的Qubits仍然是挑战。在这里，我们展示了一种基于孔旋转在锗量子点中的四个Qubit量子处理器。此外，我们在双两个阵列中定义量子点，并沿两个方向获得可控耦合。 Qubit逻辑全电动实现，并且可以将交换交互脉冲以自由地编程单个QUBET，双量标，三个QUB和四个QUBit操作，从而产生紧凑且高度连接的电路。我们执行一个量子逻辑电路，该电路产生四态绿化器-horne-Zeineer状态，并通过结合动态去耦，从而获得相干的进化。这些结果是使用量子点朝向量子误差校正和量子仿真的步骤。

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来源
《Nature》 |2021年第7851期|580-585|共6页
作者
Hendrickx Nico W.; Lawrie William I. L.; Russ Maximilian; van Riggelen Floor; de Snoo Sander L.; Schouten Raymond N.; Sammak Amir; Scappucci Giordano; Veldhorst Menno;
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作者单位

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

QuTech Delft Netherlands|Netherlands Org Appl Sci Res TNO Delft Netherlands;

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

QuTech Delft Netherlands|Delft Univ Technol Kavli Inst Nanosci Delft Netherlands;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
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入库时间 2022-08-18 23:00:54

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1. "Spectral implementation" for creating a labeled pseudo-pure state and the Bernstein-Vazirani algorithm in a four-qubit nuclear magnetic resonance quantum processor [J] . Xinhua Peng, Xiwen Zhu, Ximing Fang, The Journal of Chemical Physics . 2004,第8期

机译：在四量子位核磁共振量子处理器中创建标记的伪纯状态和Bernstein-Vazirani算法的“频谱实现”
2. Quantum state sharing of an arbitrary four-qubit GHZ-type state by using a four-qubit cluster state [J] . Yi-you Nie, Yuan-hua Li, Jun-chang Liu, Quantum Information Processing . 2011,第5期

机译：通过使用四量子位簇状态共享任意四量子位GHZ型态的量子态
3. Quantum state sharing of an arbitrary four-qubit GHZ-type state by using a four-qubit cluster state [J] . Nie Y.-Y., Li Y.-H., Liu J.-C., Quantum information processing . 2011,第5期

机译：通过使用四量子位簇状态共享任意四量子位GHZ型态的量子态
4. A Four-Qubits Code that is a Quantum Deletion Error-Correcting Code with the Optimal Length [C] . Manabu Hagiwara, Ayumu Nakayama IEEE International Symposium on Information Theory . 2020

机译：四量子位代码，它是具有最佳长度的量子删除纠错码
5. Process Integration and Performance Evaluation of Germanium-based Quantum Well Channel MOSFETs for Sub-22nm Node Digital CMOS Logic Technology [D] . Lee, Se-Hoon. 2011

机译：用于亚22纳米节点数字CMOS逻辑技术的基于锗的量子阱沟道MOSFET的工艺集成和性能评估
6. A Complete Physical Germanium-on-Silicon Quantum Dot Self-Assembly Process [O] . Amro Alkhatib, Ammar Nayfeh -1

机译：完整的硅锗物理量子点自组装过程
7. A four-qubit germanium quantum processor [O] . Nico W. Hendrickx, William I. L. Lawrie, Maximilian Russ, 2021

机译：四种Qubit锗量子处理器
8. Studies of Recombination and Reaction Processes at the Germanium Electrolyte Contact Using Internal Reflection . Untersuchung von Rekombinations- und Reaktionsvorgaengen AM Germanium-Elektrolyt-Kontakt MIT Hilfe der Internen Reflexion [R] . Dehaan, A. 1971

机译：用内反射研究锗电解质接触的重组和反应过程。 Untersuchung von Rekombinations- und Reaktionsvorgaengen am Germanium-Elektrolyt-Kontakt mIT Hilfe der Internen Reflexion

A four-qubit germanium quantum processor

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