Electronic quantum coherence encoded in temporal structures of N2+ lasing

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

doi:10.1103/PhysRevA.103.033105

Electronic quantum coherence encoded in temporal structures of N2+ lasing

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

School of Physics and Electronic Science

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

3 Scopus citations

Abstract

We experimently and theoretically investigate temporal structures of N2+ lasing at the wavelengths of 391 and 428 nm. Our results show that the resonant interaction of a femtosecond laser with N2+ ions with a picosecond dipole relaxation time will induce a long-lasting polarization, which exists in cases of both absorption and amplification of the external seed. The induced polarization will be amplified in population-inverted N2+ ions, giving rise to the retarded radiation (i.e., N2+ lasing). The temporal profile of the retarded radiation is closely related to the dipole relaxation time, population inversion density, and propagation length. The combined experimental and theoretical study reveals the physical origin of the retarded seed amplification in N2+ ions.

Original language	English
Article number	033105
Journal	Physical Review A
Volume	103
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevA.103.033105
State	Published - Mar 2021

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title = "Electronic quantum coherence encoded in temporal structures of N2+ lasing",

abstract = "We experimently and theoretically investigate temporal structures of N2+ lasing at the wavelengths of 391 and 428 nm. Our results show that the resonant interaction of a femtosecond laser with N2+ ions with a picosecond dipole relaxation time will induce a long-lasting polarization, which exists in cases of both absorption and amplification of the external seed. The induced polarization will be amplified in population-inverted N2+ ions, giving rise to the retarded radiation (i.e., N2+ lasing). The temporal profile of the retarded radiation is closely related to the dipole relaxation time, population inversion density, and propagation length. The combined experimental and theoretical study reveals the physical origin of the retarded seed amplification in N2+ ions.",

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

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doi = "10.1103/PhysRevA.103.033105",

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TY - JOUR

T1 - Electronic quantum coherence encoded in temporal structures of N2+ lasing

AU - Chen, Jinming

AU - Yao, Jinping

AU - Zhang, Zhihao

AU - Liu, Zhaoxiang

AU - Xu, Bo

AU - Wan, Yuexin

AU - Zhang, Fangbo

AU - Chu, Wei

AU - Qiao, Lingling

AU - Zhang, Haisu

AU - Wang, Zhenhua

AU - Cheng, Ya

PY - 2021/3

Y1 - 2021/3

N2 - We experimently and theoretically investigate temporal structures of N2+ lasing at the wavelengths of 391 and 428 nm. Our results show that the resonant interaction of a femtosecond laser with N2+ ions with a picosecond dipole relaxation time will induce a long-lasting polarization, which exists in cases of both absorption and amplification of the external seed. The induced polarization will be amplified in population-inverted N2+ ions, giving rise to the retarded radiation (i.e., N2+ lasing). The temporal profile of the retarded radiation is closely related to the dipole relaxation time, population inversion density, and propagation length. The combined experimental and theoretical study reveals the physical origin of the retarded seed amplification in N2+ ions.

AB - We experimently and theoretically investigate temporal structures of N2+ lasing at the wavelengths of 391 and 428 nm. Our results show that the resonant interaction of a femtosecond laser with N2+ ions with a picosecond dipole relaxation time will induce a long-lasting polarization, which exists in cases of both absorption and amplification of the external seed. The induced polarization will be amplified in population-inverted N2+ ions, giving rise to the retarded radiation (i.e., N2+ lasing). The temporal profile of the retarded radiation is closely related to the dipole relaxation time, population inversion density, and propagation length. The combined experimental and theoretical study reveals the physical origin of the retarded seed amplification in N2+ ions.

UR - https://www.scopus.com/pages/publications/85102622589

U2 - 10.1103/PhysRevA.103.033105

DO - 10.1103/PhysRevA.103.033105

M3 - 文章

AN - SCOPUS:85102622589

SN - 2469-9926

VL - 103

JO - Physical Review A

JF - Physical Review A

IS - 3

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ER -

Electronic quantum coherence encoded in temporal structures of N2+ lasing

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