Roadmap on quantum light spectroscopy

Shaul Mukamel; Matthias Freyberger; Wolfgang Schleich; Marco Bellini; Alessandro Zavatta; Gerd Leuchs; Christine Silberhorn; Robert W. Boyd; Luis Lorenzo Sánchez-Soto; André Stefanov; Marco Barbieri; Anna Paterova; Leonid Krivitsky; Sharon Shwartz; Kenji Tamasaku; Konstantin Dorfman; Frank Schlawin; Vahid Sandoghdar; Michael Raymer; Andrew Marcus; Oleg Varnavski; Theodore Goodson; Zhi Yuan Zhou; Bao Sen Shi; Shahaf Asban; Marlan Scully; Girish Agarwal; Tao Peng; Alexei V. Sokolov; Zhe Dong Zhang; M. Suhail Zubairy; Ivan A. Vartanyants; Elena Del Valle; Fabrice Laussy

doi:10.1088/1361-6455/ab69a8

Roadmap on quantum light spectroscopy

Shaul Mukamel, Matthias Freyberger, Wolfgang Schleich, Marco Bellini, Alessandro Zavatta, Gerd Leuchs, Christine Silberhorn, Robert W. Boyd, Luis Lorenzo Sánchez-Soto, André Stefanov, Marco Barbieri, Anna Paterova, Leonid Krivitsky, Sharon Shwartz, Kenji Tamasaku, Konstantin Dorfman, Frank Schlawin, Vahid Sandoghdar, Michael Raymer, Andrew MarcusOleg Varnavski, Theodore Goodson, Zhi Yuan Zhou, Bao Sen Shi, Shahaf Asban, Marlan Scully, Girish Agarwal, Tao Peng, Alexei V. Sokolov, Zhe Dong Zhang, M. Suhail Zubairy, Ivan A. Vartanyants, Elena Del Valle, Fabrice Laussy

Department of Physics

Research output: Contribution to journal › Review article › peer-review

132 Scopus citations

Abstract

Conventional spectroscopy uses classical light to detect matter properties through the variation of its response with frequencies or time delays. Quantum light opens up new avenues for spectroscopy by utilizing parameters of the quantum state of light as novel control knobs and through the variation of photon statistics by coupling to matter. This Roadmap article focuses on using quantum light as a powerful sensing and spectroscopic tool to reveal novel information about complex molecules that is not accessible by classical light. It aims at bridging the quantum optics and spectroscopy communities which normally have opposite goals: manipulating complex light states with simple matter e.g. qubits versus studying complex molecules with simple classical light, respectively. Articles cover advances in the generation and manipulation of state-of-the-art quantum light sources along with applications to sensing, spectroscopy, imaging and interferometry.

Original language	English
Article number	072002
Journal	Journal of Physics B: Atomic, Molecular and Optical Physics
Volume	53
Issue number	7
DOIs	https://doi.org/10.1088/1361-6455/ab69a8
State	Published - 14 Apr 2020

Bibliographical note

Publisher Copyright:
© 2020 IOP Publishing Ltd.

Keywords

photon statistics
quantum optics
spectroscopy

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10.1088/1361-6455/ab69a8

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Mukamel, S., Freyberger, M., Schleich, W., Bellini, M., Zavatta, A., Leuchs, G., Silberhorn, C., Boyd, R. W., Sánchez-Soto, L. L., Stefanov, A., Barbieri, M., Paterova, A., Krivitsky, L., Shwartz, S., Tamasaku, K., Dorfman, K., Schlawin, F., Sandoghdar, V., Raymer, M., ... Laussy, F. (2020). Roadmap on quantum light spectroscopy. Journal of Physics B: Atomic, Molecular and Optical Physics, 53(7), Article 072002. https://doi.org/10.1088/1361-6455/ab69a8

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abstract = "Conventional spectroscopy uses classical light to detect matter properties through the variation of its response with frequencies or time delays. Quantum light opens up new avenues for spectroscopy by utilizing parameters of the quantum state of light as novel control knobs and through the variation of photon statistics by coupling to matter. This Roadmap article focuses on using quantum light as a powerful sensing and spectroscopic tool to reveal novel information about complex molecules that is not accessible by classical light. It aims at bridging the quantum optics and spectroscopy communities which normally have opposite goals: manipulating complex light states with simple matter e.g. qubits versus studying complex molecules with simple classical light, respectively. Articles cover advances in the generation and manipulation of state-of-the-art quantum light sources along with applications to sensing, spectroscopy, imaging and interferometry.",

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doi = "10.1088/1361-6455/ab69a8",

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Mukamel, S, Freyberger, M, Schleich, W, Bellini, M, Zavatta, A, Leuchs, G, Silberhorn, C, Boyd, RW, Sánchez-Soto, LL, Stefanov, A, Barbieri, M, Paterova, A, Krivitsky, L, Shwartz, S, Tamasaku, K, Dorfman, K, Schlawin, F, Sandoghdar, V, Raymer, M, Marcus, A, Varnavski, O, Goodson, T, Zhou, ZY, Shi, BS, Asban, S, Scully, M, Agarwal, G, Peng, T, Sokolov, AV, Zhang, ZD, Zubairy, MS, Vartanyants, IA, Del Valle, E & Laussy, F 2020, 'Roadmap on quantum light spectroscopy', Journal of Physics B: Atomic, Molecular and Optical Physics, vol. 53, no. 7, 072002. https://doi.org/10.1088/1361-6455/ab69a8

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T1 - Roadmap on quantum light spectroscopy

AU - Mukamel, Shaul

AU - Freyberger, Matthias

AU - Schleich, Wolfgang

AU - Bellini, Marco

AU - Zavatta, Alessandro

AU - Leuchs, Gerd

AU - Silberhorn, Christine

AU - Boyd, Robert W.

AU - Sánchez-Soto, Luis Lorenzo

AU - Stefanov, André

AU - Barbieri, Marco

AU - Paterova, Anna

AU - Krivitsky, Leonid

AU - Shwartz, Sharon

AU - Tamasaku, Kenji

AU - Dorfman, Konstantin

AU - Schlawin, Frank

AU - Sandoghdar, Vahid

AU - Raymer, Michael

AU - Marcus, Andrew

AU - Varnavski, Oleg

AU - Goodson, Theodore

AU - Zhou, Zhi Yuan

AU - Shi, Bao Sen

AU - Asban, Shahaf

AU - Scully, Marlan

AU - Agarwal, Girish

AU - Peng, Tao

AU - Sokolov, Alexei V.

AU - Zhang, Zhe Dong

AU - Zubairy, M. Suhail

AU - Vartanyants, Ivan A.

AU - Del Valle, Elena

AU - Laussy, Fabrice

PY - 2020/4/14

Y1 - 2020/4/14

N2 - Conventional spectroscopy uses classical light to detect matter properties through the variation of its response with frequencies or time delays. Quantum light opens up new avenues for spectroscopy by utilizing parameters of the quantum state of light as novel control knobs and through the variation of photon statistics by coupling to matter. This Roadmap article focuses on using quantum light as a powerful sensing and spectroscopic tool to reveal novel information about complex molecules that is not accessible by classical light. It aims at bridging the quantum optics and spectroscopy communities which normally have opposite goals: manipulating complex light states with simple matter e.g. qubits versus studying complex molecules with simple classical light, respectively. Articles cover advances in the generation and manipulation of state-of-the-art quantum light sources along with applications to sensing, spectroscopy, imaging and interferometry.

AB - Conventional spectroscopy uses classical light to detect matter properties through the variation of its response with frequencies or time delays. Quantum light opens up new avenues for spectroscopy by utilizing parameters of the quantum state of light as novel control knobs and through the variation of photon statistics by coupling to matter. This Roadmap article focuses on using quantum light as a powerful sensing and spectroscopic tool to reveal novel information about complex molecules that is not accessible by classical light. It aims at bridging the quantum optics and spectroscopy communities which normally have opposite goals: manipulating complex light states with simple matter e.g. qubits versus studying complex molecules with simple classical light, respectively. Articles cover advances in the generation and manipulation of state-of-the-art quantum light sources along with applications to sensing, spectroscopy, imaging and interferometry.

KW - photon statistics

KW - quantum optics

KW - spectroscopy

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Roadmap on quantum light spectroscopy

Abstract

Bibliographical note

Keywords

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