Scalable quantum computing with ion-implanted dopant atoms in silicon

2018 IEEE International Electron Devices Meeting (IEDM) Pub Date : 2018-12-01 DOI:10.1109/IEDM.2018.8614498
A. Morello, G. Tosi, F. Mohiyaddin, V. Schmitt, V. Mourik, T. Botzem, A. Laucht, J. Pla, S. Tenberg, R. Savytskyy, M. Ma̧dzik, F. Hudson, A. Dzurak, K. Itoh, A. Jakob, B. C. Johnson, J. McCallum, D. Jamieson
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引用次数: 9

Abstract

We present a scalable strategy to manufacture quantum computer devices, by encoding quantum information in the combined electron-nuclear spin state of individual ion-implanted phosphorus dopant atoms in silicon. Our strategy allows a typical pitch between quantum bits of order 200 nm, and retains compatibility with the standard fabrication processes adopted in classical CMOS nanoelectronic devices. We theoretically predict fast and high-fidelity quantum logic operations, and present preliminary experimental progress towards the realization of a “flip-flop” qubit system.
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硅中离子注入掺杂原子的可扩展量子计算
我们提出了一种可扩展的制造量子计算机设备的策略,通过在硅中单个离子注入磷掺杂原子的电子-核组合自旋状态下编码量子信息。我们的策略允许200纳米量级量子比特之间的典型间距,并保持与经典CMOS纳米电子器件采用的标准制造工艺的兼容性。我们从理论上预测了快速和高保真的量子逻辑运算,并提出了实现“触发器”量子比特系统的初步实验进展。
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2018 IEEE International Electron Devices Meeting (IEDM)
2018 IEEE International Electron Devices Meeting (IEDM)
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