A low-noise on-chip coherent microwave source

Chengyu Yan; Juha Hassel; Visa Vesterinen; Jinli Zhang; Joni Ikonen; Leif Grönberg; Jan Goetz; Mikko Möttönen

doi:10.1038/s41928-021-00680-z

A low-noise on-chip coherent microwave source

Chengyu Yan^*, Juha Hassel, Visa Vesterinen, Jinli Zhang, Joni Ikonen, Leif Grönberg, Jan Goetz, Mikko Möttönen^*

^*Corresponding author for this work

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

9 Citations (Scopus)

Abstract

The scaling up of quantum computers operating in the microwave domain requires advanced control electronics, and the use of integrated components that operate at the temperature of the quantum devices is potentially beneficial. However, such an approach requires ultralow power dissipation and high signal quality to ensure quantum-coherent operations. Here we report an on-chip device that is based on a Josephson junction coupled to a spiral resonator and is capable of coherent continuous-wave microwave emission. We show that the characteristics of the device accurately follow a theory based on the perturbative treatment of a capacitively shunted Josephson junction as the gain element. The infidelity of typical quantum gate operations due to phase noise of this cryogenic 25 pW microwave source is less than 0.1% up to 10 ms evolution time, which is below the infidelity caused by dephasing in state-of-the-art superconducting qubits. Together with future cryogenic amplitude and phase modulation techniques, our approach may lead to scalable cryogenic control systems for quantum processors.

Original language	English
Number of pages	8
Journal	Nature Electronics
Volume	4
Issue number	12
Early online date	9 Dec 2021
DOIs	https://doi.org/10.1038/s41928-021-00680-z
Publication status	Published - Dec 2021
MoE publication type	A1 Journal article-refereed

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10.1038/s41928-021-00680-z

https://arxiv.org/abs/2103.07617

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title = "A low-noise on-chip coherent microwave source",

abstract = "The scaling up of quantum computers operating in the microwave domain requires advanced control electronics, and the use of integrated components that operate at the temperature of the quantum devices is potentially beneficial. However, such an approach requires ultralow power dissipation and high signal quality to ensure quantum-coherent operations. Here we report an on-chip device that is based on a Josephson junction coupled to a spiral resonator and is capable of coherent continuous-wave microwave emission. We show that the characteristics of the device accurately follow a theory based on the perturbative treatment of a capacitively shunted Josephson junction as the gain element. The infidelity of typical quantum gate operations due to phase noise of this cryogenic 25 pW microwave source is less than 0.1% up to 10 ms evolution time, which is below the infidelity caused by dephasing in state-of-the-art superconducting qubits. Together with future cryogenic amplitude and phase modulation techniques, our approach may lead to scalable cryogenic control systems for quantum processors.",

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AU - Yan, Chengyu

AU - Hassel, Juha

AU - Vesterinen, Visa

AU - Zhang, Jinli

AU - Ikonen, Joni

AU - Grönberg, Leif

AU - Goetz, Jan

AU - Möttönen, Mikko

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AB - The scaling up of quantum computers operating in the microwave domain requires advanced control electronics, and the use of integrated components that operate at the temperature of the quantum devices is potentially beneficial. However, such an approach requires ultralow power dissipation and high signal quality to ensure quantum-coherent operations. Here we report an on-chip device that is based on a Josephson junction coupled to a spiral resonator and is capable of coherent continuous-wave microwave emission. We show that the characteristics of the device accurately follow a theory based on the perturbative treatment of a capacitively shunted Josephson junction as the gain element. The infidelity of typical quantum gate operations due to phase noise of this cryogenic 25 pW microwave source is less than 0.1% up to 10 ms evolution time, which is below the infidelity caused by dephasing in state-of-the-art superconducting qubits. Together with future cryogenic amplitude and phase modulation techniques, our approach may lead to scalable cryogenic control systems for quantum processors.

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A low-noise on-chip coherent microwave source

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