Optical Synthesis of Large-Amplitude Squeezed Coherent-State Superpositions with Minimal Resources

K. Huang; H. Le Jeannic; J. Ruaudel; V. B. Verma; M. D. Shaw; F. Marsili; S. W. Nam; E. Wu; H. Zeng; Y. C. Jeong; R. Filip; O. Morin; J. Laurat

doi:10.1103/PhysRevLett.115.023602

Optical Synthesis of Large-Amplitude Squeezed Coherent-State Superpositions with Minimal Resources

K. Huang, H. Le Jeannic, J. Ruaudel, V. B. Verma, M. D. Shaw, F. Marsili, S. W. Nam, E. Wu, H. Zeng, Y. C. Jeong, R. Filip, O. Morin, J. Laurat

Institute for Advanced Study in Precision Spectroscopy

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

106 Scopus citations

Abstract

We propose and experimentally realize a novel versatile protocol that allows the quantum state engineering of heralded optical coherent-state superpositions. This scheme relies on a two-mode squeezed state, linear mixing, and a n-photon detection. It is optimally using expensive non-Gaussian resources to build up only the key non-Gaussian part of the targeted state. In the experimental case of a two-photon detection based on high-efficiency superconducting nanowire single-photon detectors, the freely propagating state exhibits a 67% fidelity with a squeezed even coherent-state superposition with a size |α|2=3. The demonstrated procedure and the achieved rate will facilitate the use of such superpositions in subsequent protocols, including fundamental tests and optical hybrid quantum information implementations.

Original language	English
Article number	023602
Journal	Physical Review Letters
Volume	115
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.115.023602
State	Published - 9 Jul 2015

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title = "Optical Synthesis of Large-Amplitude Squeezed Coherent-State Superpositions with Minimal Resources",

abstract = "We propose and experimentally realize a novel versatile protocol that allows the quantum state engineering of heralded optical coherent-state superpositions. This scheme relies on a two-mode squeezed state, linear mixing, and a n-photon detection. It is optimally using expensive non-Gaussian resources to build up only the key non-Gaussian part of the targeted state. In the experimental case of a two-photon detection based on high-efficiency superconducting nanowire single-photon detectors, the freely propagating state exhibits a 67\% fidelity with a squeezed even coherent-state superposition with a size |α|2=3. The demonstrated procedure and the achieved rate will facilitate the use of such superpositions in subsequent protocols, including fundamental tests and optical hybrid quantum information implementations.",

author = "K. Huang and \{Le Jeannic\}, H. and J. Ruaudel and Verma, \{V. B.\} and Shaw, \{M. D.\} and F. Marsili and Nam, \{S. W.\} and E. Wu and H. Zeng and Jeong, \{Y. C.\} and R. Filip and O. Morin and J. Laurat",

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doi = "10.1103/PhysRevLett.115.023602",

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AU - Huang, K.

AU - Le Jeannic, H.

AU - Ruaudel, J.

AU - Verma, V. B.

AU - Shaw, M. D.

AU - Marsili, F.

AU - Nam, S. W.

AU - Wu, E.

AU - Zeng, H.

AU - Jeong, Y. C.

AU - Filip, R.

AU - Morin, O.

AU - Laurat, J.

PY - 2015/7/9

Y1 - 2015/7/9

N2 - We propose and experimentally realize a novel versatile protocol that allows the quantum state engineering of heralded optical coherent-state superpositions. This scheme relies on a two-mode squeezed state, linear mixing, and a n-photon detection. It is optimally using expensive non-Gaussian resources to build up only the key non-Gaussian part of the targeted state. In the experimental case of a two-photon detection based on high-efficiency superconducting nanowire single-photon detectors, the freely propagating state exhibits a 67% fidelity with a squeezed even coherent-state superposition with a size |α|2=3. The demonstrated procedure and the achieved rate will facilitate the use of such superpositions in subsequent protocols, including fundamental tests and optical hybrid quantum information implementations.

AB - We propose and experimentally realize a novel versatile protocol that allows the quantum state engineering of heralded optical coherent-state superpositions. This scheme relies on a two-mode squeezed state, linear mixing, and a n-photon detection. It is optimally using expensive non-Gaussian resources to build up only the key non-Gaussian part of the targeted state. In the experimental case of a two-photon detection based on high-efficiency superconducting nanowire single-photon detectors, the freely propagating state exhibits a 67% fidelity with a squeezed even coherent-state superposition with a size |α|2=3. The demonstrated procedure and the achieved rate will facilitate the use of such superpositions in subsequent protocols, including fundamental tests and optical hybrid quantum information implementations.

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Optical Synthesis of Large-Amplitude Squeezed Coherent-State Superpositions with Minimal Resources

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