Effect of self-focusing of an intense cosh-Gaussian laser beam on second harmonic generation in a collisionless plasma: Higher-order paraxial theory

Effect of self-focusing of an intense cosh-Gaussian laser beam on second harmonic generation in a collisionless plasma: Higher-order paraxial theory

•Analytical and numerical study of the self-focusing effect of cosh-Gaussian laser beam on second harmonic generation in plasma.•Higher-order paraxial ray approximation is used to study second harmonic generation.•This study is done in the presence of relativistic and ponderomotive nonlinearities.•E...

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Bibliographic Details
Published in:Chinese journal of physics (Taipei) Vol. 77; pp. 2639 - 2654
Main Author: Purohit, Gunjan
Format: Journal Article
Language:English
Published: Elsevier B.V 01-06-2022
Subjects:
Collisionless plasma
Cosh Gaussian laser beam
Electron plasma wave
Higher-order paraxial theory
Second harmonic generation
Second harmonic generation
Higher-order paraxial theory
Collisionless plasma
Electron plasma wave
Cosh Gaussian laser beam
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Summary:•Analytical and numerical study of the self-focusing effect of cosh-Gaussian laser beam on second harmonic generation in plasma.•Higher-order paraxial ray approximation is used to study second harmonic generation.•This study is done in the presence of relativistic and ponderomotive nonlinearities.•Electron plasma wave generated by an intense cosh-Gaussian laser beam is the main source of second harmonic generation.•The electric field of the second harmonic wave increases significantly in the higher-order paraxial region as well as at higher values of decentred parameter (b), incident laser intensity (a), and relative plasma density (ωp0/ω0). This paper presents the study of second harmonic generation in a collisionless plasma by an intense self-focused cosh-Gaussian laser beam under the combined effect of relativistic and ponderomotive nonlinearities. The second harmonics of a cosh-Gaussian laser beam is generated by the excitation of an electron plasma wave at the pump frequency. The excited electron plasma wave coupled with the pump laser beam and generate the radiation of double frequency. This study is carried out in a higher-order paraxial ray approximation where higher order terms are taken into account in the expansion of the dielectric function and the eikonal. Nonlinear differential equations have been established for the self-focusing of cosh-Gaussian laser beam in the plasma, the generation of electron plasma wave at the pump frequency, and the second harmonic generation. Numerical simulations have been carried out to investigate the effects of laser and plasma parameters such as decentred parameter (b), incident laser intensity (a), and relative plasma density (ωp0/ω0) on the self-focusing of the cosh-Gaussian laser beam and the electric field associated with electron plasma wave and second harmonic wave. A well-established set of laser and plasma parameters have been used in numerical analysis. The results show that the focusing of the cosh-Gaussian laser beam leads to an increase in the electric field of the electron plasma wave and the second harmonic wave. The results are also compared to the paraxial-ray approximation. The focusing of the cosh-Gaussian laser beam in the plasma is strengthened in the higher-order paraxial region, which increases the electric field of both the electron plasma wave and the second harmonic wave at high values of b, a, and ωp0/ω0. The electric field of the second harmonic wave increases with an increase in the value of the decentred parameter (b) of the cosh-Gaussian laser beam in the higher-order paraxial region, which shows that the cosh-Gaussian laser beam is much better than the Gaussian laser beam for the production of second harmonic generation in plasma. Red, green, blue and black curves for b = 0, 0.4, 0.6 and 0.8 respectively. [Display omitted]
ISSN:0577-9073
DOI:10.1016/j.cjph.2022.05.003