Extremely nonlinear Raman interaction of an ultrashort nitrogen ion laser with an impulsively excited molecular wave packet

Zhaoxiang Liu; Jinping Yao; Haisu Zhang; Bo Xu; Jinming Chen; Fangbo Zhang; Zhihao Zhang; Yuexin Wan; Wei Chu; Zhenhua Wang; Ya Cheng

doi:10.1103/PhysRevA.101.043404

Extremely nonlinear Raman interaction of an ultrashort nitrogen ion laser with an impulsively excited molecular wave packet

Zhaoxiang Liu
, Jinping Yao
, Haisu Zhang
, Bo Xu
, Jinming Chen
, Fangbo Zhang
, Zhihao Zhang
, Yuexin Wan
, Wei Chu
, Zhenhua Wang
, Ya Cheng

School of Physics and Electronic Science

CAS - Shanghai Institute of Optics and Fine Mechanics
University of Chinese Academy of Sciences
ShanghaiTech University
East China Normal University
Shanxi University
Shandong Normal University

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

22 Scopus citations

Abstract

We report on the generation of cascaded rotational Raman scattering up to 58th order in coherently excited CO2 molecules. Raman scattering with more than 600 sidebands is obtained using an intense femtosecond laser to impulsively excite rotational coherence and femtosecond-laser-induced N2+ lasing to generate cascaded Raman signals. This configuration allows this experiment to be performed with a single femtosecond laser beam at free-space standoff locations. It is revealed that the efficient spectral extension of Raman signals is attributed to the specific structures of N2+ lasing in the spectral and temporal domains and the ideal spatial overlap of the femtosecond laser and N2+ lasing. A Raman spectrum extending above 2000cm-1 naturally corresponds to a femtosecond pulse train due to the periodic revivals of molecular rotational wave packets.

Original language	English
Article number	043404
Journal	Physical Review A
Volume	101
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevA.101.043404
State	Published - Apr 2020

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title = "Extremely nonlinear Raman interaction of an ultrashort nitrogen ion laser with an impulsively excited molecular wave packet",

abstract = "We report on the generation of cascaded rotational Raman scattering up to 58th order in coherently excited CO2 molecules. Raman scattering with more than 600 sidebands is obtained using an intense femtosecond laser to impulsively excite rotational coherence and femtosecond-laser-induced N2+ lasing to generate cascaded Raman signals. This configuration allows this experiment to be performed with a single femtosecond laser beam at free-space standoff locations. It is revealed that the efficient spectral extension of Raman signals is attributed to the specific structures of N2+ lasing in the spectral and temporal domains and the ideal spatial overlap of the femtosecond laser and N2+ lasing. A Raman spectrum extending above 2000cm-1 naturally corresponds to a femtosecond pulse train due to the periodic revivals of molecular rotational wave packets.",

author = "Zhaoxiang Liu and Jinping Yao and Haisu Zhang and Bo Xu and Jinming Chen and Fangbo Zhang and Zhihao Zhang and Yuexin Wan and Wei Chu and Zhenhua Wang and Ya Cheng",

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doi = "10.1103/PhysRevA.101.043404",

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T1 - Extremely nonlinear Raman interaction of an ultrashort nitrogen ion laser with an impulsively excited molecular wave packet

AU - Liu, Zhaoxiang

AU - Yao, Jinping

AU - Zhang, Haisu

AU - Xu, Bo

AU - Chen, Jinming

AU - Zhang, Fangbo

AU - Zhang, Zhihao

AU - Wan, Yuexin

AU - Chu, Wei

AU - Wang, Zhenhua

AU - Cheng, Ya

PY - 2020/4

Y1 - 2020/4

N2 - We report on the generation of cascaded rotational Raman scattering up to 58th order in coherently excited CO2 molecules. Raman scattering with more than 600 sidebands is obtained using an intense femtosecond laser to impulsively excite rotational coherence and femtosecond-laser-induced N2+ lasing to generate cascaded Raman signals. This configuration allows this experiment to be performed with a single femtosecond laser beam at free-space standoff locations. It is revealed that the efficient spectral extension of Raman signals is attributed to the specific structures of N2+ lasing in the spectral and temporal domains and the ideal spatial overlap of the femtosecond laser and N2+ lasing. A Raman spectrum extending above 2000cm-1 naturally corresponds to a femtosecond pulse train due to the periodic revivals of molecular rotational wave packets.

AB - We report on the generation of cascaded rotational Raman scattering up to 58th order in coherently excited CO2 molecules. Raman scattering with more than 600 sidebands is obtained using an intense femtosecond laser to impulsively excite rotational coherence and femtosecond-laser-induced N2+ lasing to generate cascaded Raman signals. This configuration allows this experiment to be performed with a single femtosecond laser beam at free-space standoff locations. It is revealed that the efficient spectral extension of Raman signals is attributed to the specific structures of N2+ lasing in the spectral and temporal domains and the ideal spatial overlap of the femtosecond laser and N2+ lasing. A Raman spectrum extending above 2000cm-1 naturally corresponds to a femtosecond pulse train due to the periodic revivals of molecular rotational wave packets.

UR - https://www.scopus.com/pages/publications/85085195895

U2 - 10.1103/PhysRevA.101.043404

DO - 10.1103/PhysRevA.101.043404

M3 - 文章

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SN - 2469-9926

VL - 101

JO - Physical Review A

JF - Physical Review A

IS - 4

M1 - 043404

ER -

Extremely nonlinear Raman interaction of an ultrashort nitrogen ion laser with an impulsively excited molecular wave packet

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