Cryogenic III-V and Nb electronics integrated on silicon for large-scale quantum computing platforms

Jaeyong Jeong; Seong Kwang Kim; Yoon Je Suh; Jisung Lee; Joonyoung Choi; Joon Pyo Kim; Bong Ho Kim; Juhyuk Park; Joonsup Shim; Nahyun Rheem; Chan Jik Lee; Younjung Jo; Dae Myeong Geum; Seung Young Park; Jongmin Kim; Sanghyeon Kim

doi:10.1038/s41467-024-55077-1

Cryogenic III-V and Nb electronics integrated on silicon for large-scale quantum computing platforms

Jaeyong Jeong
, Seong Kwang Kim
, Yoon Je Suh
, Jisung Lee
, Joonyoung Choi
, Joon Pyo Kim
, Bong Ho Kim
, Juhyuk Park
, Joonsup Shim
, Nahyun Rheem
, Chan Jik Lee
, Younjung Jo
, Dae Myeong Geum
, Seung Young Park
, Jongmin Kim
, Sanghyeon Kim

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

8 Scopus citations

Abstract

Quantum computers now encounter the significant challenge of scalability, similar to the issue that classical computing faced previously. Recent results in high-fidelity spin qubits manufactured with a Si CMOS technology, along with demonstrations that cryogenic CMOS-based control/readout electronics can be integrated into the same chip or die, opens up an opportunity to break out the challenges of qubit size, I/O, and integrability. However, the power consumption of cryogenic CMOS-based control/readout electronics cannot support thousands or millions of qubits. Here, we show that III–V two-dimensional electron gas and Nb superconductor-based cryogenic electronics can be integrated with Si and operate at extremely low power levels, enabling the control and readout for millions of qubits. Our devices offer a unity gain cutoff frequency of 601 GHz, a unity power gain cutoff frequency of 593 GHz, and a low noise indication factor IDgm−1 of 0.21VmmS−1 at 4 K using more than 10 times less power consumption than CMOS.

Original language	English
Article number	10809
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-55077-1
State	Published - Dec 2024

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Jeong, J., Kim, S. K., Suh, Y. J., Lee, J., Choi, J., Kim, J. P., Kim, B. H., Park, J., Shim, J., Rheem, N., Lee, C. J., Jo, Y., Geum, D. M., Park, S. Y., Kim, J., & Kim, S. (2024). Cryogenic III-V and Nb electronics integrated on silicon for large-scale quantum computing platforms. Nature Communications, 15(1), Article 10809. https://doi.org/10.1038/s41467-024-55077-1

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title = "Cryogenic III-V and Nb electronics integrated on silicon for large-scale quantum computing platforms",

abstract = "Quantum computers now encounter the significant challenge of scalability, similar to the issue that classical computing faced previously. Recent results in high-fidelity spin qubits manufactured with a Si CMOS technology, along with demonstrations that cryogenic CMOS-based control/readout electronics can be integrated into the same chip or die, opens up an opportunity to break out the challenges of qubit size, I/O, and integrability. However, the power consumption of cryogenic CMOS-based control/readout electronics cannot support thousands or millions of qubits. Here, we show that III–V two-dimensional electron gas and Nb superconductor-based cryogenic electronics can be integrated with Si and operate at extremely low power levels, enabling the control and readout for millions of qubits. Our devices offer a unity gain cutoff frequency of 601 GHz, a unity power gain cutoff frequency of 593 GHz, and a low noise indication factor IDgm−1 of 0.21VmmS−1 at 4 K using more than 10 times less power consumption than CMOS.",

author = "Jaeyong Jeong and Kim, \{Seong Kwang\} and Suh, \{Yoon Je\} and Jisung Lee and Joonyoung Choi and Kim, \{Joon Pyo\} and Kim, \{Bong Ho\} and Juhyuk Park and Joonsup Shim and Nahyun Rheem and Lee, \{Chan Jik\} and Younjung Jo and Geum, \{Dae Myeong\} and Park, \{Seung Young\} and Jongmin Kim and Sanghyeon Kim",

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AU - Kim, Joon Pyo

AU - Kim, Bong Ho

AU - Park, Juhyuk

AU - Shim, Joonsup

AU - Rheem, Nahyun

AU - Lee, Chan Jik

AU - Jo, Younjung

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AU - Kim, Jongmin

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AB - Quantum computers now encounter the significant challenge of scalability, similar to the issue that classical computing faced previously. Recent results in high-fidelity spin qubits manufactured with a Si CMOS technology, along with demonstrations that cryogenic CMOS-based control/readout electronics can be integrated into the same chip or die, opens up an opportunity to break out the challenges of qubit size, I/O, and integrability. However, the power consumption of cryogenic CMOS-based control/readout electronics cannot support thousands or millions of qubits. Here, we show that III–V two-dimensional electron gas and Nb superconductor-based cryogenic electronics can be integrated with Si and operate at extremely low power levels, enabling the control and readout for millions of qubits. Our devices offer a unity gain cutoff frequency of 601 GHz, a unity power gain cutoff frequency of 593 GHz, and a low noise indication factor IDgm−1 of 0.21VmmS−1 at 4 K using more than 10 times less power consumption than CMOS.

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Cryogenic III-V and Nb electronics integrated on silicon for large-scale quantum computing platforms

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