Baseband control of single-electron silicon spin qubits in two dimensions

Florian K. Unseld; Brennan Undseth; Eline Raymenants; Yuta Matsumoto; Sander L. de Snoo; Saurabh Karwal; Oriol Pietx-Casas; Alexander S. Ivlev; Marcel Meyer; Amir Sammak; Menno Veldhorst; Giordano Scappucci; Lieven M.K. Vandersypen

doi:10.1038/s41467-025-60351-x

Baseband control of single-electron silicon spin qubits in two dimensions

Florian K. Unseld, Brennan Undseth, Eline Raymenants, Yuta Matsumoto, Sander L. de Snoo, Saurabh Karwal, Oriol Pietx-Casas, Alexander S. Ivlev, Marcel Meyer, Amir Sammak, Menno Veldhorst, Giordano Scappucci, Lieven M.K. Vandersypen^*

^*Corresponding author for this work

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Abstract

Micromagnet-enabled electric-dipole spin resonance (EDSR) is an established method for high-fidelity single-spin control in silicon, although so far experiments have been restricted to one-dimensional arrays. In contrast, qubit control based on hopping spins has recently emerged as a compelling alternative, with high-fidelity baseband control realized in sparse two-dimensional hole arrays in germanium. In this work, we commission a ²⁸Si/SiGe 2 × 2 quantum dot array both as a four-qubit device using EDSR and as a two-qubit device using baseband hopping control. We establish a lower bound on the fidelity of the hopping gate of 99.50(6)%, which is similar to the average fidelity of the resonant gate. The hopping gate also circumvents the transient pulse-induced resonance shift from heating observed during EDSR operation. To motivate hopping spins as an attractive means of scaling silicon spin-qubit arrays, we propose an extensible nanomagnet design that enables engineered baseband control of large spin arrays.

Original language	English
Article number	5605
Number of pages	12
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-60351-x
Publication status	Published - 2025

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title = "Baseband control of single-electron silicon spin qubits in two dimensions",

abstract = "Micromagnet-enabled electric-dipole spin resonance (EDSR) is an established method for high-fidelity single-spin control in silicon, although so far experiments have been restricted to one-dimensional arrays. In contrast, qubit control based on hopping spins has recently emerged as a compelling alternative, with high-fidelity baseband control realized in sparse two-dimensional hole arrays in germanium. In this work, we commission a 28Si/SiGe 2 × 2 quantum dot array both as a four-qubit device using EDSR and as a two-qubit device using baseband hopping control. We establish a lower bound on the fidelity of the hopping gate of 99.50(6)%, which is similar to the average fidelity of the resonant gate. The hopping gate also circumvents the transient pulse-induced resonance shift from heating observed during EDSR operation. To motivate hopping spins as an attractive means of scaling silicon spin-qubit arrays, we propose an extensible nanomagnet design that enables engineered baseband control of large spin arrays.",

author = "Unseld, {Florian K.} and Brennan Undseth and Eline Raymenants and Yuta Matsumoto and {de Snoo}, {Sander L.} and Saurabh Karwal and Oriol Pietx-Casas and Ivlev, {Alexander S.} and Marcel Meyer and Amir Sammak and Menno Veldhorst and Giordano Scappucci and Vandersypen, {Lieven M.K.}",

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AU - Unseld, Florian K.

AU - Undseth, Brennan

AU - Raymenants, Eline

AU - Matsumoto, Yuta

AU - de Snoo, Sander L.

AU - Karwal, Saurabh

AU - Pietx-Casas, Oriol

AU - Ivlev, Alexander S.

AU - Meyer, Marcel

AU - Sammak, Amir

AU - Veldhorst, Menno

AU - Scappucci, Giordano

AU - Vandersypen, Lieven M.K.

PY - 2025

Y1 - 2025

N2 - Micromagnet-enabled electric-dipole spin resonance (EDSR) is an established method for high-fidelity single-spin control in silicon, although so far experiments have been restricted to one-dimensional arrays. In contrast, qubit control based on hopping spins has recently emerged as a compelling alternative, with high-fidelity baseband control realized in sparse two-dimensional hole arrays in germanium. In this work, we commission a 28Si/SiGe 2 × 2 quantum dot array both as a four-qubit device using EDSR and as a two-qubit device using baseband hopping control. We establish a lower bound on the fidelity of the hopping gate of 99.50(6)%, which is similar to the average fidelity of the resonant gate. The hopping gate also circumvents the transient pulse-induced resonance shift from heating observed during EDSR operation. To motivate hopping spins as an attractive means of scaling silicon spin-qubit arrays, we propose an extensible nanomagnet design that enables engineered baseband control of large spin arrays.

AB - Micromagnet-enabled electric-dipole spin resonance (EDSR) is an established method for high-fidelity single-spin control in silicon, although so far experiments have been restricted to one-dimensional arrays. In contrast, qubit control based on hopping spins has recently emerged as a compelling alternative, with high-fidelity baseband control realized in sparse two-dimensional hole arrays in germanium. In this work, we commission a 28Si/SiGe 2 × 2 quantum dot array both as a four-qubit device using EDSR and as a two-qubit device using baseband hopping control. We establish a lower bound on the fidelity of the hopping gate of 99.50(6)%, which is similar to the average fidelity of the resonant gate. The hopping gate also circumvents the transient pulse-induced resonance shift from heating observed during EDSR operation. To motivate hopping spins as an attractive means of scaling silicon spin-qubit arrays, we propose an extensible nanomagnet design that enables engineered baseband control of large spin arrays.

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Baseband control of single-electron silicon spin qubits in two dimensions

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