Related papers: High-fidelity dispersive spin sensing in a tuneable unit cell of silicon MOS quantum dots

High-fidelity dispersive spin sensing in a tuneable unit cell of silicon MOS quantum dots

URL: http://arxiv.org/abs/2505.10435v1
Date: Thu, 15 May 2025 15:53:09 GMT
Title: High-fidelity dispersive spin sensing in a tuneable unit cell of silicon MOS quantum dots
Authors: Constance Lainé, Giovanni A. Oakes, Virginia Ciriano-Tejel, Jacob F. Chittock-Wood, Lorenzo Peri, Michael A. Fogarty, Sofia M. Patomäki, Stefan Kubicek, David F. Wise, Ross C. C. Leon, M. Fernando Gonzalez-Zalba, John J. L. Morton,
Abstract summary: Metal-oxide-semiconductor (MOS) technology is a promising platform for developing quantum computers based on spin qubits.<n>Here, we demonstrate a compact dispersive spin-qubit sensor, a single-electron box (SEB), within a bilinear unit cell of planar MOS quantum dots (QDs) fabricated using an industrial grade 300 mm wafer process.<n>By independent gate control of the SEB and double-quantum-dot tunnel rates, we optimize the sensor to achieve a readout fidelity of 99.92% in 340us (99% in 20us)
Score: 0.648213451348322
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Metal-oxide-semiconductor (MOS) technology is a promising platform for developing quantum computers based on spin qubits. Scaling this approach will benefit from compact and sensitive sensors that minimize constraints on qubit connectivity while being industrially manufacturable. Here, we demonstrate a compact dispersive spin-qubit sensor, a single-electron box (SEB), within a bilinear unit cell of planar MOS quantum dots (QDs) fabricated using an industrial grade 300 mm wafer process. By independent gate control of the SEB and double-quantum-dot tunnel rates, we optimize the sensor to achieve a readout fidelity of 99.92% in 340us (99% in 20us), fidelity values on a par with the best obtained with less compact sensors. Furthermore, we develop a Hidden Markov Model of the two-electron spin dynamics that enables a more accurate calculation of the measurement outcome and hence readout fidelity. Our results show how high-fidelity sensors can be introduced within silicon spin-qubit architectures while maintaining sufficient qubit connectivity as well as providing faster readout and more efficient initialisation schemes.

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