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Buried nanomagnet realizing high-speed/low-variability silicon spin qubits: implementable in error-correctable large-scale quantum computers

机译：埋藏的纳米磁体实现高速/低变性硅旋转QUBITS：可在纠错的大型量子计算机中实现

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We propose a buried nanomagnet (BNM) realizing highspeed/low-variability silicon spin qubit operation, inspired by buried wiring technology, for the first time. High-speed quantum-gate operation results from large slanting magnetic-field generated by the BNM disposed quite close to a spin qubit, and low-variation of fidelity thanks to the self-aligned fabrication process. Employing TCAD-based simulation, we demonstrate that the BNM realizes 10 times faster Rabi oscillation (faster spin-flip) than previous works and >99% fidelity under certain process variations. Also, the proposed BNM arrangement is implementable for error-correctable large-scale quantum computers employing a 2D-latticed qubit layout. This technology paves the way to practical large-scale quantum computers with silicon.

机译：我们提出了一种掩埋的纳米磁磁磁块（BNM），实现了高速/低变化的硅旋转量程，这是第一次受到埋地布线技术的启发。高速量子栅操作由由BNM产生的大倾斜磁场产生，该偏置近距离旋转qubit，并且由于自对准的制造工艺而低于待遇的保真度。采用基于TCAD的仿真，我们证明了BNM比以前的作品更快地实现了10倍的Rabi振荡（更快的旋转翻转），并且在某些过程变化下的保真度> 99％。此外，所提出的BNM布置可用于采用2D晶圆Qubit布局的误差可纠正的大型量子计算机。该技术为具有硅的实用大型量子计算机铺平了道路。

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《IEEE Symposium on VLSI Technology》|2021年|1-2|共2页
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Shota Iizuka; Kimihiko Kato; Atsushi Yagishita; Hidehiro Asai; Tetsuya Ueda; Hiroshi Oka; Junichi Hattori; Tsutomu Ikegami; Koichi Fukuda; Takahiro Mori;
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Computers; Wiring; Qubit; Quantum dots; Layout; Metals; Logic gates;

机译：电脑;接线;qubit;量子点;布局;金属;逻辑门;

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专利

1. Error Correcting Codes In Quantum Theory, Scheme For Reducing Decoherence In Quantum Computer Memory, Correcting Quantum Computer Errors, Qubits Based On Quantum Spins, And Other Topics: A fomentation-Dissipation Model [J] . K.N.P. Kumar Advances in Physics Theories and Applications . 2013,第1期

机译：误差校正量子理论中的校正码，用于减少量子计算机存储器中的转移的方案，校正量子计算机误差，基于量子旋转的Qubits，以及其他主题：耗散模型
2. Large-scale silicon quantum photonics implementing arbitrary two-qubit processing [J] . Qiang Xiaogang, Zhou Xiaoqi, Wang Jianwei, Nature photonics . 2018,第9期

机译：大型硅量子光子，实现任意双量标处理
3. Simulation of static and random errors on Grover’s search algorithm implemented in an Ising nuclear spin chain quantum computer with a few qubits [J] . T Gorin, L Lara, G V Lopez Journal of Physics, B. Atomic, Molecular and Optical Physics: An Institute of Physics Journal . 2010,第8期

机译：在具有几个量子位的Ising核自旋链量子计算机中实现的Grover搜索算法上的静态和随机误差仿真
4. Buried nanomagnet realizing high-speed/low-variability silicon spin qubits: implementable in error-correctable large-scale quantum computers [C] . Shota Iizuka, Kimihiko Kato, Atsushi Yagishita, Symposium on VLSI Circuits . 2021

机译：埋藏的纳米磁体实现高速/低变性硅旋转QUBITS：可在纠错的大型量子计算机中实现
5. Spin-orbit Interaction and Electron Spin Qubits in Silicon Quantum Dots [D] . Ferdous, Rifat. 2018

机译：硅量子点中的自旋轨道相互作用和电子自旋量子位
6. Spin states vibrations and spin relaxation in molecular nanomagnets and spin qubits: a critical perspective [O] . Luis Escalera-Moreno, José J. Baldoví, Alejandro Gaita-Ariño, 2018

机译：分子纳米磁体和自旋量子位的自旋态振动和自旋弛豫：一个重要的视角
7. Simulation of static and random errors on Grover's search algorithm implemented in an Ising nuclear spin chain quantum computer with a few qubits [O] . T Gorin, L Lara, G V López 2010

机译：几个Qubits在核旋转链量子计算机中实现了格罗弗搜索算法静态和随机误差的仿真
8. Solid State Quantum Computing Using Spin Qubits in Silicon Quantum Dots (QCCM) [R] . Eriksson, M., Lagally, M., Friesen, M., 2009

机译：利用硅量子点中的自旋量子点进行固态量子计算（QCCm）

Buried nanomagnet realizing high-speed/low-variability silicon spin qubits: implementable in error-correctable large-scale quantum computers

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