Classical versus quantum views of intense laser pulse propagation in gases

We study the behavior of reduced models for the propagation of intense laser pulses in atomic gases. The models we consider incorporate ionization, blueshifting, and other nonlinear propagation effects in an ab initio manner, by explicitly taking into account the microscopic electron dynamics. Numer...

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Bibliographic Details
Published in:Journal of physics. B, Atomic, molecular, and optical physics Atomic, molecular, and optical physics, 2019-06, Vol.52 (12), p.125601
Main Authors: Berman, S A, Chandre, C, Dubois, J, Perin, M, Uzer, T
Format: Article
Language:English
Subjects:
Atomic Physics
Chaotic Dynamics
high harmonic generation
multiphoton or tunneling ionization and excitation
nonlinear pulse propagation
Nonlinear Sciences
phase space methods
Physics
Plasma Physics
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Summary:We study the behavior of reduced models for the propagation of intense laser pulses in atomic gases. The models we consider incorporate ionization, blueshifting, and other nonlinear propagation effects in an ab initio manner, by explicitly taking into account the microscopic electron dynamics. Numerical simulations of the propagation of ultrashort linearly-polarized and elliptically-polarized laser pulses over experimentally-relevant propagation distances are presented. We compare the behavior of models where the electrons are treated classically with those where they are treated quantum-mechanically. A classical equivalent to the ground state is found, which maximizes the agreement between the quantum and classical predictions of the single-atom ionization probability as a function of laser intensity. We show that this translates into quantitative agreement between the quantum and classical models for the laser field evolution during propagation through gases of ground-state atoms. This agreement is exploited to provide a classical perspective on low- and high-order harmonic generation in linearly-polarized fields. In addition, we demonstrate the stability of the polarization of a nearly-linearly-polarized pulse using a two-dimensional model.
ISSN:0953-4075
1361-6455
DOI:10.1088/1361-6455/ab1c12