Demonstration of an ac Josephson junction laser

M. C. Cassidy; A. Bruno; S. Rubbert; M. Irfan; J. Kammhuber; R. N. Schouten; A. R. Akhmerov; L. P. Kouwenhoven

doi:10.1126/science.aah6640

Demonstration of an ac Josephson junction laser

M. C. Cassidy, A. Bruno, S. Rubbert, M. Irfan, J. Kammhuber, R. N. Schouten, A. R. Akhmerov, L. P. Kouwenhoven^*

^*Corresponding author for this work

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

60 Citations (Scopus)

Abstract

Superconducting electronic devices have reemerged as contenders for both classical and quantum computing due to their fast operation speeds, low dissipation, and long coherence times. An ultimate demonstration of coherence is lasing. We use one of the fundamental aspects of superconductivity, the ac Josephson effect, to demonstrate a laser made from a Josephson junction strongly coupled to a multimode superconducting cavity. A dc voltage bias applied across the junction provides a source of microwave photons, and the circuit's nonlinearity allows for efficient down-conversion of higher-order Josephson frequencies to the cavity's fundamental mode. The simple fabrication and operation allows for easy integration with a range of quantum devices, allowing for efficient on-chip generation of coherent microwave photons at low temperatures.

Original language	English
Pages (from-to)	939-942
Number of pages	4
Journal	Science
Volume	355
Issue number	6328
DOIs	https://doi.org/10.1126/science.aah6640
Publication status	Published - 3 Mar 2017

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title = "Demonstration of an ac Josephson junction laser",

abstract = "Superconducting electronic devices have reemerged as contenders for both classical and quantum computing due to their fast operation speeds, low dissipation, and long coherence times. An ultimate demonstration of coherence is lasing. We use one of the fundamental aspects of superconductivity, the ac Josephson effect, to demonstrate a laser made from a Josephson junction strongly coupled to a multimode superconducting cavity. A dc voltage bias applied across the junction provides a source of microwave photons, and the circuit's nonlinearity allows for efficient down-conversion of higher-order Josephson frequencies to the cavity's fundamental mode. The simple fabrication and operation allows for easy integration with a range of quantum devices, allowing for efficient on-chip generation of coherent microwave photons at low temperatures.",

author = "Cassidy, {M. C.} and A. Bruno and S. Rubbert and M. Irfan and J. Kammhuber and Schouten, {R. N.} and Akhmerov, {A. R.} and Kouwenhoven, {L. P.}",

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AU - Cassidy, M. C.

AU - Bruno, A.

AU - Rubbert, S.

AU - Irfan, M.

AU - Kammhuber, J.

AU - Schouten, R. N.

AU - Akhmerov, A. R.

AU - Kouwenhoven, L. P.

PY - 2017/3/3

Y1 - 2017/3/3

N2 - Superconducting electronic devices have reemerged as contenders for both classical and quantum computing due to their fast operation speeds, low dissipation, and long coherence times. An ultimate demonstration of coherence is lasing. We use one of the fundamental aspects of superconductivity, the ac Josephson effect, to demonstrate a laser made from a Josephson junction strongly coupled to a multimode superconducting cavity. A dc voltage bias applied across the junction provides a source of microwave photons, and the circuit's nonlinearity allows for efficient down-conversion of higher-order Josephson frequencies to the cavity's fundamental mode. The simple fabrication and operation allows for easy integration with a range of quantum devices, allowing for efficient on-chip generation of coherent microwave photons at low temperatures.

AB - Superconducting electronic devices have reemerged as contenders for both classical and quantum computing due to their fast operation speeds, low dissipation, and long coherence times. An ultimate demonstration of coherence is lasing. We use one of the fundamental aspects of superconductivity, the ac Josephson effect, to demonstrate a laser made from a Josephson junction strongly coupled to a multimode superconducting cavity. A dc voltage bias applied across the junction provides a source of microwave photons, and the circuit's nonlinearity allows for efficient down-conversion of higher-order Josephson frequencies to the cavity's fundamental mode. The simple fabrication and operation allows for easy integration with a range of quantum devices, allowing for efficient on-chip generation of coherent microwave photons at low temperatures.

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Demonstration of an ac Josephson junction laser

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