Approximating vibronic spectroscopy with imperfect quantum optics

William R. Clements; Jelmer J. Renema; Andreas Eckstein; Antonio A. Valido; Adriana Lita; Thomas Gerrits; Sae Woo Nam; W. Steven Kolthammer; Joonsuk Huh; Ian A. Walmsley

doi:10.1088/1361-6455/aaf031

Approximating vibronic spectroscopy with imperfect quantum optics

William R. Clements, Jelmer J. Renema, Andreas Eckstein, Antonio A. Valido, Adriana Lita, Thomas Gerrits, Sae Woo Nam, W. Steven Kolthammer, Joonsuk Huh, Ian A. Walmsley

Department of Chemistry

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

34 Citations (Scopus)

Abstract

We study the impact of experimental imperfections on a recently proposed protocol for performing quantum simulations of vibronic spectroscopy. Specifically, we propose a method for quantifying the impact of these imperfections, optimizing an experiment to account for them, and benchmarking the results against a classical simulation method. We illustrate our findings using a proof of principle experimental simulation of part of the vibronic spectrum of tropolone. Our findings will inform the design of future experiments aiming to simulate the spectra of large molecules beyond the reach of current classical computers.

Original language	English
Article number	245503
Journal	Journal of Physics B: Atomic, Molecular and Optical Physics
Volume	51
Issue number	24
DOIs	https://doi.org/10.1088/1361-6455/aaf031
Publication status	Published - 2018 Nov 23

Bibliographical note

Publisher Copyright:
© 2018 IOP Publishing Ltd.

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics
Condensed Matter Physics

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10.1088/1361-6455/aaf031

Cite this

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abstract = "We study the impact of experimental imperfections on a recently proposed protocol for performing quantum simulations of vibronic spectroscopy. Specifically, we propose a method for quantifying the impact of these imperfections, optimizing an experiment to account for them, and benchmarking the results against a classical simulation method. We illustrate our findings using a proof of principle experimental simulation of part of the vibronic spectrum of tropolone. Our findings will inform the design of future experiments aiming to simulate the spectra of large molecules beyond the reach of current classical computers.",

keywords = "boson sampling, quantum chemistry, quantum optics, quantum simulation, squeezed light, vibronic spectroscopy",

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AU - Clements, William R.

AU - Renema, Jelmer J.

AU - Eckstein, Andreas

AU - Valido, Antonio A.

AU - Lita, Adriana

AU - Gerrits, Thomas

AU - Nam, Sae Woo

AU - Kolthammer, W. Steven

AU - Huh, Joonsuk

AU - Walmsley, Ian A.

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N2 - We study the impact of experimental imperfections on a recently proposed protocol for performing quantum simulations of vibronic spectroscopy. Specifically, we propose a method for quantifying the impact of these imperfections, optimizing an experiment to account for them, and benchmarking the results against a classical simulation method. We illustrate our findings using a proof of principle experimental simulation of part of the vibronic spectrum of tropolone. Our findings will inform the design of future experiments aiming to simulate the spectra of large molecules beyond the reach of current classical computers.

AB - We study the impact of experimental imperfections on a recently proposed protocol for performing quantum simulations of vibronic spectroscopy. Specifically, we propose a method for quantifying the impact of these imperfections, optimizing an experiment to account for them, and benchmarking the results against a classical simulation method. We illustrate our findings using a proof of principle experimental simulation of part of the vibronic spectrum of tropolone. Our findings will inform the design of future experiments aiming to simulate the spectra of large molecules beyond the reach of current classical computers.

KW - boson sampling

KW - quantum chemistry

KW - quantum optics

KW - quantum simulation

KW - squeezed light

KW - vibronic spectroscopy

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Approximating vibronic spectroscopy with imperfect quantum optics

Abstract

Bibliographical note

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