Qubits made by advanced semiconductor manufacturing

A. M.J. Zwerver; T. Krähenmann; S. V. Amitonov; J. M. Boter; G. Droulers; M. Lodari; N. Samkharadze; G. Zheng; G. Scappucci; M. Veldhorst; L. M.K. Vandersypen; null More Authors

doi:10.1038/s41928-022-00727-9

Qubits made by advanced semiconductor manufacturing

A. M.J. Zwerver, T. Krähenmann, S. V. Amitonov, J. M. Boter, G. Droulers, M. Lodari, N. Samkharadze, G. Zheng, G. Scappucci, M. Veldhorst, L. M.K. Vandersypen^*, More Authors

^*Corresponding author for this work

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

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Abstract

Full-scale quantum computers require the integration of millions of qubits, and the potential of using industrial semiconductor manufacturing to meet this need has driven the development of quantum computing in silicon quantum dots. However, fabrication has so far relied on electron-beam lithography and, with a few exceptions, conventional lift-off processes that suffer from low yield and poor uniformity. Here we report quantum dots that are hosted at a ²⁸Si/²⁸SiO₂ interface and fabricated in a 300 mm semiconductor manufacturing facility using all-optical lithography and fully industrial processing. With this approach, we achieve nanoscale gate patterns with excellent yield. In the multi-electron regime, the quantum dots allow good tunnel barrier control—a crucial feature for fault-tolerant two-qubit gates. Single-spin qubit operation using magnetic resonance in the few-electron regime reveals relaxation times of over 1 s at 1 T and coherence times of over 3 ms.

Original language	English
Pages (from-to)	184-190
Journal	Nature Electronics
Volume	5
Issue number	3
DOIs	https://doi.org/10.1038/s41928-022-00727-9
Publication status	Published - 2022

Bibliographical note

correction DOI 10.1038/s41928-022-00772-4
D. Correas-Serrano is the corrected in the HTML and PDF versions of the article

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title = "Qubits made by advanced semiconductor manufacturing",

abstract = "Full-scale quantum computers require the integration of millions of qubits, and the potential of using industrial semiconductor manufacturing to meet this need has driven the development of quantum computing in silicon quantum dots. However, fabrication has so far relied on electron-beam lithography and, with a few exceptions, conventional lift-off processes that suffer from low yield and poor uniformity. Here we report quantum dots that are hosted at a 28Si/28SiO2 interface and fabricated in a 300 mm semiconductor manufacturing facility using all-optical lithography and fully industrial processing. With this approach, we achieve nanoscale gate patterns with excellent yield. In the multi-electron regime, the quantum dots allow good tunnel barrier control—a crucial feature for fault-tolerant two-qubit gates. Single-spin qubit operation using magnetic resonance in the few-electron regime reveals relaxation times of over 1 s at 1 T and coherence times of over 3 ms.",

author = "Zwerver, {A. M.J.} and T. Kr{\"a}henmann and Amitonov, {S. V.} and Boter, {J. M.} and G. Droulers and M. Lodari and N. Samkharadze and G. Zheng and G. Scappucci and M. Veldhorst and Vandersypen, {L. M.K.} and {More Authors}",

note = "correction DOI 10.1038/s41928-022-00772-4 D. Correas-Serrano is the corrected in the HTML and PDF versions of the article",

year = "2022",

doi = "10.1038/s41928-022-00727-9",

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AU - Zwerver, A. M.J.

AU - Krähenmann, T.

AU - Amitonov, S. V.

AU - Boter, J. M.

AU - Droulers, G.

AU - Lodari, M.

AU - Samkharadze, N.

AU - Zheng, G.

AU - Scappucci, G.

AU - Veldhorst, M.

AU - Vandersypen, L. M.K.

AU - More Authors, null

N1 - correction DOI 10.1038/s41928-022-00772-4 D. Correas-Serrano is the corrected in the HTML and PDF versions of the article

PY - 2022

Y1 - 2022

N2 - Full-scale quantum computers require the integration of millions of qubits, and the potential of using industrial semiconductor manufacturing to meet this need has driven the development of quantum computing in silicon quantum dots. However, fabrication has so far relied on electron-beam lithography and, with a few exceptions, conventional lift-off processes that suffer from low yield and poor uniformity. Here we report quantum dots that are hosted at a 28Si/28SiO2 interface and fabricated in a 300 mm semiconductor manufacturing facility using all-optical lithography and fully industrial processing. With this approach, we achieve nanoscale gate patterns with excellent yield. In the multi-electron regime, the quantum dots allow good tunnel barrier control—a crucial feature for fault-tolerant two-qubit gates. Single-spin qubit operation using magnetic resonance in the few-electron regime reveals relaxation times of over 1 s at 1 T and coherence times of over 3 ms.

AB - Full-scale quantum computers require the integration of millions of qubits, and the potential of using industrial semiconductor manufacturing to meet this need has driven the development of quantum computing in silicon quantum dots. However, fabrication has so far relied on electron-beam lithography and, with a few exceptions, conventional lift-off processes that suffer from low yield and poor uniformity. Here we report quantum dots that are hosted at a 28Si/28SiO2 interface and fabricated in a 300 mm semiconductor manufacturing facility using all-optical lithography and fully industrial processing. With this approach, we achieve nanoscale gate patterns with excellent yield. In the multi-electron regime, the quantum dots allow good tunnel barrier control—a crucial feature for fault-tolerant two-qubit gates. Single-spin qubit operation using magnetic resonance in the few-electron regime reveals relaxation times of over 1 s at 1 T and coherence times of over 3 ms.

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EP - 190

JO - Nature Electronics

JF - Nature Electronics

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Qubits made by advanced semiconductor manufacturing

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