Observing collisions beyond the secular approximation limit

Junyang Ma; Haisu Zhang; Bruno Lavorel; Franck Billard; Edouard Hertz; Jian Wu; Christian Boulet; Jean Michel Hartmann; Olivier Faucher

doi:10.1038/s41467-019-13706-0

Observing collisions beyond the secular approximation limit

Junyang Ma
, Haisu Zhang
, Bruno Lavorel
, Franck Billard
, Edouard Hertz
, Jian Wu
, Christian Boulet
, Jean Michel Hartmann
, Olivier Faucher^*

^*此作品的通讯作者

精密光谱科学与技术高等研究院

Laboratoire Interdisciplinaire Carnot de Bourgogne
Shanxi University
CNRS
Sorbonne Université

科研成果: 期刊稿件 › 文章 › 同行评审

31 引用（Scopus）

摘要

Quantum coherence plays an essential role in diverse natural phenomena and technological applications. The unavoidable coupling of the quantum system to an uncontrolled environment incurs dissipation that is often described using the secular approximation. Here we probe the limit of this approximation in the rotational relaxation of molecules due to thermal collisions by using the laser-kicked molecular rotor as a model system. Specifically, rotational coherences in N₂O gas (diluted in He) are created by two successive nonresonant short and intense laser pulses and probed by studying the change of amplitude of the rotational alignment echo with the gas density. By interrogating the system at the early stage of its collisional relaxation, we observe a significant variation of the dissipative influence of collisions with the time of appearance of the echo, featuring a decoherence process that is well reproduced by the nonsecular quantum master equation for modeling molecular collisions.

源语言	英语
文章编号	5780
期刊	Nature Communications
卷	10
期	1
DOI	https://doi.org/10.1038/s41467-019-13706-0
出版状态	已出版 - 1 12月 2019

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abstract = "Quantum coherence plays an essential role in diverse natural phenomena and technological applications. The unavoidable coupling of the quantum system to an uncontrolled environment incurs dissipation that is often described using the secular approximation. Here we probe the limit of this approximation in the rotational relaxation of molecules due to thermal collisions by using the laser-kicked molecular rotor as a model system. Specifically, rotational coherences in N2O gas (diluted in He) are created by two successive nonresonant short and intense laser pulses and probed by studying the change of amplitude of the rotational alignment echo with the gas density. By interrogating the system at the early stage of its collisional relaxation, we observe a significant variation of the dissipative influence of collisions with the time of appearance of the echo, featuring a decoherence process that is well reproduced by the nonsecular quantum master equation for modeling molecular collisions.",

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AU - Zhang, Haisu

AU - Lavorel, Bruno

AU - Billard, Franck

AU - Hertz, Edouard

AU - Wu, Jian

AU - Boulet, Christian

AU - Hartmann, Jean Michel

AU - Faucher, Olivier

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N2 - Quantum coherence plays an essential role in diverse natural phenomena and technological applications. The unavoidable coupling of the quantum system to an uncontrolled environment incurs dissipation that is often described using the secular approximation. Here we probe the limit of this approximation in the rotational relaxation of molecules due to thermal collisions by using the laser-kicked molecular rotor as a model system. Specifically, rotational coherences in N2O gas (diluted in He) are created by two successive nonresonant short and intense laser pulses and probed by studying the change of amplitude of the rotational alignment echo with the gas density. By interrogating the system at the early stage of its collisional relaxation, we observe a significant variation of the dissipative influence of collisions with the time of appearance of the echo, featuring a decoherence process that is well reproduced by the nonsecular quantum master equation for modeling molecular collisions.

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Observing collisions beyond the secular approximation limit

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