Femtosecond time-domain observation of atmospheric absorption in the near-infrared spectrum

T. J. Hammond; Sylvain Monchocé; Chunmei Zhang; Graham G. Brown; P. B. Corkum; D. M. Villeneuve

doi:10.1103/PhysRevA.94.063410

Femtosecond time-domain observation of atmospheric absorption in the near-infrared spectrum

T. J. Hammond^*, Sylvain Monchocé, Chunmei Zhang, Graham G. Brown, P. B. Corkum, D. M. Villeneuve

^*Corresponding author for this work

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

10 Citations (Scopus)

Abstract

As light propagates through a medium, absorption caused by electronic or rovibrational transitions is evident in the transmitted spectrum. The incident electromagnetic field polarizes the medium and the absorption is due to the imaginary part of the linear susceptibility. In the time domain, the field establishes a coherence in the medium that radiates out of phase with the initial field. This coherence can persist for tens of picoseconds in atmospheric molecules such as H2O. We propagate a few-cycle laser pulse centered at 1.8μm through the atmosphere and measure the long-lasting molecular coherence in the time domain by high-order harmonic cross correlation. The measured optical free-induction decay of the pulse is compared with a calculation based on the calculated rovibrational spectrum of H2O absorption.

Original language	English
Article number	063410
Journal	Physical Review A
Volume	94
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevA.94.063410
Publication status	Published - 9 Dec 2016
Externally published	Yes

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title = "Femtosecond time-domain observation of atmospheric absorption in the near-infrared spectrum",

abstract = "As light propagates through a medium, absorption caused by electronic or rovibrational transitions is evident in the transmitted spectrum. The incident electromagnetic field polarizes the medium and the absorption is due to the imaginary part of the linear susceptibility. In the time domain, the field establishes a coherence in the medium that radiates out of phase with the initial field. This coherence can persist for tens of picoseconds in atmospheric molecules such as H2O. We propagate a few-cycle laser pulse centered at 1.8μm through the atmosphere and measure the long-lasting molecular coherence in the time domain by high-order harmonic cross correlation. The measured optical free-induction decay of the pulse is compared with a calculation based on the calculated rovibrational spectrum of H2O absorption.",

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T1 - Femtosecond time-domain observation of atmospheric absorption in the near-infrared spectrum

AU - Hammond, T. J.

AU - Monchocé, Sylvain

AU - Zhang, Chunmei

AU - Brown, Graham G.

AU - Corkum, P. B.

AU - Villeneuve, D. M.

PY - 2016/12/9

Y1 - 2016/12/9

N2 - As light propagates through a medium, absorption caused by electronic or rovibrational transitions is evident in the transmitted spectrum. The incident electromagnetic field polarizes the medium and the absorption is due to the imaginary part of the linear susceptibility. In the time domain, the field establishes a coherence in the medium that radiates out of phase with the initial field. This coherence can persist for tens of picoseconds in atmospheric molecules such as H2O. We propagate a few-cycle laser pulse centered at 1.8μm through the atmosphere and measure the long-lasting molecular coherence in the time domain by high-order harmonic cross correlation. The measured optical free-induction decay of the pulse is compared with a calculation based on the calculated rovibrational spectrum of H2O absorption.

AB - As light propagates through a medium, absorption caused by electronic or rovibrational transitions is evident in the transmitted spectrum. The incident electromagnetic field polarizes the medium and the absorption is due to the imaginary part of the linear susceptibility. In the time domain, the field establishes a coherence in the medium that radiates out of phase with the initial field. This coherence can persist for tens of picoseconds in atmospheric molecules such as H2O. We propagate a few-cycle laser pulse centered at 1.8μm through the atmosphere and measure the long-lasting molecular coherence in the time domain by high-order harmonic cross correlation. The measured optical free-induction decay of the pulse is compared with a calculation based on the calculated rovibrational spectrum of H2O absorption.

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DO - 10.1103/PhysRevA.94.063410

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Femtosecond time-domain observation of atmospheric absorption in the near-infrared spectrum

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