Scalable on-chip multiplexing of silicon single and double quantum dots

Heorhii Bohuslavskyi; Alberto Ronzani; Joel Hätinen; Arto Rantala; Andrey Shchepetov; Panu Koppinen; Janne S. Lehtinen; Mika Prunnila

doi:10.1038/s42005-024-01806-3

Scalable on-chip multiplexing of silicon single and double quantum dots

Heorhii Bohuslavskyi^*
, Alberto Ronzani
, Joel Hätinen
, Arto Rantala
, Andrey Shchepetov
, Panu Koppinen
, Janne S. Lehtinen^*
, Mika Prunnila^*

^*Corresponding author for this work

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

7 Citations (Scopus)

Abstract

Owing to the maturity of complementary metal oxide semiconductor (CMOS) microelectronics, qubits realized with spins in silicon quantum dots (QDs) are considered among the most promising technologies for building scalable quantum computers. For this goal, ultra-low-power on-chip cryogenic CMOS (cryo-CMOS) electronics for control, read-out, and interfacing of the qubits is an important milestone. We report on-chip interfacing of tunable electron and hole QDs by a 64-channel cryo-CMOS multiplexer with less-than-detectable static power dissipation. We analyze charge noise and measure state-of-the-art addition energies and gate lever arm parameters in the QDs. We correlate low noise in QDs and sharp turn-on characteristics in cryogenic transistors, both fabricated with the same gate stack. Finally, we demonstrate that our hybrid quantum-CMOS technology provides a route to scalable interfacing of a large number of QD devices, enabling, for example, variability analysis and QD qubit geometry optimization, which are prerequisites for building large-scale silicon-based quantum computers.

Original language	English
Article number	323
Journal	Communications Physics
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s42005-024-01806-3
Publication status	Published - Dec 2024
MoE publication type	A1 Journal article-refereed

Funding

We would like to thank the VTT\u2019s operators and process engineers for supporting the fabrication in the OtaNano and VTT Micronova cleanroom facilities. We gratefully acknowledge the financial support from the European Union\u2019s Horizon 2020 research and innovation program under Grant Agreement Nos. 688539 (http://mosquito.eu),766853 (http://www.efined-h2020.eu/) and 824109 European Microkelvin Platform (EMP), the Academy of Finland project QuMOS (project numbers 288907 and 287768), ETHEC (No. 322580), and Center of Excellence program project (No 312294). We also acknowledge funding from Business Finland through Quantum Technology Industrial (QuTI) project no. 128291. H.B. acknowledges support from the Academy of Finland through the individual postdoctoral fellowship, project CRYOPROC (No. 350325) and the funding from Horizon Europe project Qu-Pilot project (No. 101113983). A.Ron. acknowledges the support from the Academy of Finland through his personal fellowship grant, project SUPSI (No. 356542).

Keywords

Hadrons
MOSFET devices
Photons
Quantum optics
Qubits
Semiconductor quantum dots
Silicon wafers

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10.1038/s42005-024-01806-3Licence: CC BY

Cite this

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title = "Scalable on-chip multiplexing of silicon single and double quantum dots",

abstract = "Owing to the maturity of complementary metal oxide semiconductor (CMOS) microelectronics, qubits realized with spins in silicon quantum dots (QDs) are considered among the most promising technologies for building scalable quantum computers. For this goal, ultra-low-power on-chip cryogenic CMOS (cryo-CMOS) electronics for control, read-out, and interfacing of the qubits is an important milestone. We report on-chip interfacing of tunable electron and hole QDs by a 64-channel cryo-CMOS multiplexer with less-than-detectable static power dissipation. We analyze charge noise and measure state-of-the-art addition energies and gate lever arm parameters in the QDs. We correlate low noise in QDs and sharp turn-on characteristics in cryogenic transistors, both fabricated with the same gate stack. Finally, we demonstrate that our hybrid quantum-CMOS technology provides a route to scalable interfacing of a large number of QD devices, enabling, for example, variability analysis and QD qubit geometry optimization, which are prerequisites for building large-scale silicon-based quantum computers.",

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author = "Heorhii Bohuslavskyi and Alberto Ronzani and Joel H{\"a}tinen and Arto Rantala and Andrey Shchepetov and Panu Koppinen and Lehtinen, \{Janne S.\} and Mika Prunnila",

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year = "2024",

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doi = "10.1038/s42005-024-01806-3",

language = "English",

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journal = "Communications Physics",

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AU - Bohuslavskyi, Heorhii

AU - Ronzani, Alberto

AU - Hätinen, Joel

AU - Rantala, Arto

AU - Shchepetov, Andrey

AU - Koppinen, Panu

AU - Lehtinen, Janne S.

AU - Prunnila, Mika

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2024/12

Y1 - 2024/12

N2 - Owing to the maturity of complementary metal oxide semiconductor (CMOS) microelectronics, qubits realized with spins in silicon quantum dots (QDs) are considered among the most promising technologies for building scalable quantum computers. For this goal, ultra-low-power on-chip cryogenic CMOS (cryo-CMOS) electronics for control, read-out, and interfacing of the qubits is an important milestone. We report on-chip interfacing of tunable electron and hole QDs by a 64-channel cryo-CMOS multiplexer with less-than-detectable static power dissipation. We analyze charge noise and measure state-of-the-art addition energies and gate lever arm parameters in the QDs. We correlate low noise in QDs and sharp turn-on characteristics in cryogenic transistors, both fabricated with the same gate stack. Finally, we demonstrate that our hybrid quantum-CMOS technology provides a route to scalable interfacing of a large number of QD devices, enabling, for example, variability analysis and QD qubit geometry optimization, which are prerequisites for building large-scale silicon-based quantum computers.

AB - Owing to the maturity of complementary metal oxide semiconductor (CMOS) microelectronics, qubits realized with spins in silicon quantum dots (QDs) are considered among the most promising technologies for building scalable quantum computers. For this goal, ultra-low-power on-chip cryogenic CMOS (cryo-CMOS) electronics for control, read-out, and interfacing of the qubits is an important milestone. We report on-chip interfacing of tunable electron and hole QDs by a 64-channel cryo-CMOS multiplexer with less-than-detectable static power dissipation. We analyze charge noise and measure state-of-the-art addition energies and gate lever arm parameters in the QDs. We correlate low noise in QDs and sharp turn-on characteristics in cryogenic transistors, both fabricated with the same gate stack. Finally, we demonstrate that our hybrid quantum-CMOS technology provides a route to scalable interfacing of a large number of QD devices, enabling, for example, variability analysis and QD qubit geometry optimization, which are prerequisites for building large-scale silicon-based quantum computers.

KW - Hadrons

KW - MOSFET devices

KW - Photons

KW - Quantum optics

KW - Qubits

KW - Semiconductor quantum dots

KW - Silicon wafers

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DO - 10.1038/s42005-024-01806-3

M3 - Article

AN - SCOPUS:85206206560

SN - 2399-3650

VL - 7

JO - Communications Physics

JF - Communications Physics

IS - 1

M1 - 323

ER -

Scalable on-chip multiplexing of silicon single and double quantum dots

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Scalable on-chip multiplexing of low-noise silicon electron and hole quantum dots

JOGATE: Josephson Gated Transistors and Electronics

SUPSI: Si-based Josephson field-effect transistors

CRYOPROC: Cryogenic silicon neuromorphic processor for quantum computing

Cite this

Scalable on-chip multiplexing of silicon single and double quantum dots

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Research output

Scalable on-chip multiplexing of low-noise silicon electron and hole quantum dots

Projects

JOGATE: Josephson Gated Transistors and Electronics

SUPSI: Si-based Josephson field-effect transistors

CRYOPROC: Cryogenic silicon neuromorphic processor for quantum computing

Cite this