The origins of noise in the Zeeman splitting of spin qubits in natural-silicon devices

Juan S. Rojas-Arias; Yohei Kojima; Kenta Takeda; Peter Stano; Takashi Nakajima; Jun Yoneda; Akito Noiri; Takashi Kobayashi; Daniel Loss; Seigo Tarucha

doi:10.1038/s41534-025-01150-6

The origins of noise in the Zeeman splitting of spin qubits in natural-silicon devices

Juan S. Rojas-Arias^*
, Yohei Kojima
, Kenta Takeda
, Peter Stano
, Takashi Nakajima
, Jun Yoneda
, Akito Noiri
, Takashi Kobayashi
, Daniel Loss
, Seigo Tarucha^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

We measure and analyze noise-induced energy-fluctuations of spin qubits defined in quantum dots made of isotopically natural silicon. Combining Ramsey, time-correlation of single-shot measurements, and CPMG experiments, we cover the qubit noise power spectrum over a frequency range of nine orders of magnitude without any gaps. We find that the low-frequency noise spectrum is similar across three different devices suggesting that it is dominated by the hyperfine coupling to nuclei. The effects of charge noise are smaller, but not negligible, and are device dependent as confirmed from the noise cross-correlations. We also observe differences to spectra reported in GaAs [Phys. Rev. Lett. 118, 177702 (2017), Phys. Rev. Lett. 101, 236803 (2008)], which we attribute to the presence of the valley degree of freedom in silicon. Finally, we observe T2* to increase upon increasing the external magnetic field, which we speculate is due to the increasing field gradient of the micromagnet suppressing nuclear spin diffusion.

Original language	English
Article number	9
Journal	npj Quantum Information
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41534-025-01150-6
State	Published - Dec 2026
Externally published	Yes

Bibliographical note

Publisher Copyright:
© The Author(s) 2025.

ASJC Scopus subject areas

Computer Science (miscellaneous)
Statistical and Nonlinear Physics
Computer Networks and Communications
Computational Theory and Mathematics

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title = "The origins of noise in the Zeeman splitting of spin qubits in natural-silicon devices",

abstract = "We measure and analyze noise-induced energy-fluctuations of spin qubits defined in quantum dots made of isotopically natural silicon. Combining Ramsey, time-correlation of single-shot measurements, and CPMG experiments, we cover the qubit noise power spectrum over a frequency range of nine orders of magnitude without any gaps. We find that the low-frequency noise spectrum is similar across three different devices suggesting that it is dominated by the hyperfine coupling to nuclei. The effects of charge noise are smaller, but not negligible, and are device dependent as confirmed from the noise cross-correlations. We also observe differences to spectra reported in GaAs [Phys. Rev. Lett. 118, 177702 (2017), Phys. Rev. Lett. 101, 236803 (2008)], which we attribute to the presence of the valley degree of freedom in silicon. Finally, we observe T2* to increase upon increasing the external magnetic field, which we speculate is due to the increasing field gradient of the micromagnet suppressing nuclear spin diffusion.",

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doi = "10.1038/s41534-025-01150-6",

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AU - Rojas-Arias, Juan S.

AU - Kojima, Yohei

AU - Takeda, Kenta

AU - Stano, Peter

AU - Nakajima, Takashi

AU - Yoneda, Jun

AU - Noiri, Akito

AU - Kobayashi, Takashi

AU - Loss, Daniel

AU - Tarucha, Seigo

PY - 2026/12

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N2 - We measure and analyze noise-induced energy-fluctuations of spin qubits defined in quantum dots made of isotopically natural silicon. Combining Ramsey, time-correlation of single-shot measurements, and CPMG experiments, we cover the qubit noise power spectrum over a frequency range of nine orders of magnitude without any gaps. We find that the low-frequency noise spectrum is similar across three different devices suggesting that it is dominated by the hyperfine coupling to nuclei. The effects of charge noise are smaller, but not negligible, and are device dependent as confirmed from the noise cross-correlations. We also observe differences to spectra reported in GaAs [Phys. Rev. Lett. 118, 177702 (2017), Phys. Rev. Lett. 101, 236803 (2008)], which we attribute to the presence of the valley degree of freedom in silicon. Finally, we observe T2* to increase upon increasing the external magnetic field, which we speculate is due to the increasing field gradient of the micromagnet suppressing nuclear spin diffusion.

AB - We measure and analyze noise-induced energy-fluctuations of spin qubits defined in quantum dots made of isotopically natural silicon. Combining Ramsey, time-correlation of single-shot measurements, and CPMG experiments, we cover the qubit noise power spectrum over a frequency range of nine orders of magnitude without any gaps. We find that the low-frequency noise spectrum is similar across three different devices suggesting that it is dominated by the hyperfine coupling to nuclei. The effects of charge noise are smaller, but not negligible, and are device dependent as confirmed from the noise cross-correlations. We also observe differences to spectra reported in GaAs [Phys. Rev. Lett. 118, 177702 (2017), Phys. Rev. Lett. 101, 236803 (2008)], which we attribute to the presence of the valley degree of freedom in silicon. Finally, we observe T2* to increase upon increasing the external magnetic field, which we speculate is due to the increasing field gradient of the micromagnet suppressing nuclear spin diffusion.

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The origins of noise in the Zeeman splitting of spin qubits in natural-silicon devices

Abstract

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