Quantum Microwave Parametric Interferometer

F. Kronowetter; F. Fesquet; M. Renger; K. Honasoge; Y. Nojiri; K. Inomata; Y. Nakamura; A. Marx; R. Gross; K. G. Fedorov

doi:10.1103/PhysRevApplied.20.024049

Quantum Microwave Parametric Interferometer

F. Kronowetter, F. Fesquet, M. Renger, K. Honasoge, Y. Nojiri, K. Inomata, Y. Nakamura, A. Marx, R. Gross, K. G. Fedorov

Lehrstuhl für Technische Physik

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

7 Zitate (Scopus)

Abstract

Classical interferometers are indispensable tools for the precise determination of various physical quantities. Their accuracy is bound by the standard quantum limit. This limit can be overcome by using quantum states or nonlinear quantum elements. Here, we present the experimental study of a nonlinear Josephson interferometer operating in the microwave regime. Our quantum microwave parametric interferometer (QUMPI) is based on superconducting flux-driven Josephson parametric amplifiers combined with linear microwave elements. We perform a systematic analysis of the implemented QUMPI. We find that its interferometric power exceeds the shot-noise limit and observe sub-Poissonian photon statistics in the output modes. Furthermore, we identify a low-gain operation regime of the QUMPI that is essential for optimal quantum measurements in quantum illumination protocols.

Originalsprache	Englisch
Aufsatznummer	024049
Fachzeitschrift	Physical Review Applied
Jahrgang	20
Ausgabenummer	2
DOIs	https://doi.org/10.1103/PhysRevApplied.20.024049
Publikationsstatus	Veröffentlicht - Aug. 2023

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10.1103/PhysRevApplied.20.024049

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AU - Kronowetter, F.

AU - Fesquet, F.

AU - Renger, M.

AU - Honasoge, K.

AU - Nojiri, Y.

AU - Inomata, K.

AU - Nakamura, Y.

AU - Marx, A.

AU - Gross, R.

AU - Fedorov, K. G.

PY - 2023/8

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N2 - Classical interferometers are indispensable tools for the precise determination of various physical quantities. Their accuracy is bound by the standard quantum limit. This limit can be overcome by using quantum states or nonlinear quantum elements. Here, we present the experimental study of a nonlinear Josephson interferometer operating in the microwave regime. Our quantum microwave parametric interferometer (QUMPI) is based on superconducting flux-driven Josephson parametric amplifiers combined with linear microwave elements. We perform a systematic analysis of the implemented QUMPI. We find that its interferometric power exceeds the shot-noise limit and observe sub-Poissonian photon statistics in the output modes. Furthermore, we identify a low-gain operation regime of the QUMPI that is essential for optimal quantum measurements in quantum illumination protocols.

AB - Classical interferometers are indispensable tools for the precise determination of various physical quantities. Their accuracy is bound by the standard quantum limit. This limit can be overcome by using quantum states or nonlinear quantum elements. Here, we present the experimental study of a nonlinear Josephson interferometer operating in the microwave regime. Our quantum microwave parametric interferometer (QUMPI) is based on superconducting flux-driven Josephson parametric amplifiers combined with linear microwave elements. We perform a systematic analysis of the implemented QUMPI. We find that its interferometric power exceeds the shot-noise limit and observe sub-Poissonian photon statistics in the output modes. Furthermore, we identify a low-gain operation regime of the QUMPI that is essential for optimal quantum measurements in quantum illumination protocols.

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Quantum Microwave Parametric Interferometer

Abstract

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