Electron acceleration by a cosh-Gaussian laser beam driven electron plasma wave: extended paraxial theory

Electron acceleration by a cosh-Gaussian laser beam driven electron plasma wave: extended paraxial theory

Excitation of electron plasma wave by an intense short laser pulse is relevant to electron acceleration process in laser plasma interactions. This work presents the self-focusing of an intense cosh-Gaussian laser beam in collissionless plasma with relativistic and ponderomotive nonlinearities in the...

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Bibliographic Details
Published in:Optical and quantum electronics Vol. 53; no. 10
Main Authors: Purohit, Gunjan, Gaur, Bineet, Raizada, Amita, Kothiyal, Pradeep
Format: Journal Article
Language:English
Published: New York Springer US 01-10-2021
Springer Nature B.V
Subjects:
Amplitudes
Characterization and Evaluation of Materials
Computer Communication Networks
Electrical Engineering
Electron acceleration
Electron plasma
Excitation
Focusing
Gaussian beams (optics)
Laser beams
Laser plasma interactions
Laser plasmas
Lasers
Nonlinearity
Numerical analysis
Optical Devices
Optics
Parameters
Photonics
Physics
Physics and Astronomy
Plasma interactions
Plasma waves
Plasmas (physics)
Relativistic effects
Cosh-Gaussian laser beam
Self-focusing
Relativistic-ponderomotive nonlinearity
Electron acceleration
Electron plasma wave
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Summary:Excitation of electron plasma wave by an intense short laser pulse is relevant to electron acceleration process in laser plasma interactions. This work presents the self-focusing of an intense cosh-Gaussian laser beam in collissionless plasma with relativistic and ponderomotive nonlinearities in the extended-paraxial region. Further, the effect of self-focusing of the cosh-Gaussian laser beam on the excitation of electron plasma wave and on subsequent electron acceleration has been investigated. Analytical expressions for the beam width parameter/intensity of cosh-Gaussian laser beam and the electron plasma wave have been established and solved numerically. The energy of the accelerated electrons has also been obtained. The strong self-focusing of the cosh-Gaussian laser beam in plasmas stimulates a large amplitude electron plasma wave, which further accelerates the electrons. The well-established laser and plasma parameters have been used in numerical computation. The results have been compared with the paraxial ray approximation, the Gaussian profile of the laser beam, and only relativistic nonlinearity. The numerical results show that the focusing of the cosh-Gaussian laser beam, the amplitude of the electron plasma wave, and the energy gain by the electrons increases in the extended-paraxial region, when relativistic and ponderomotive nonlinearities are operative simultaneously. In addition, it has also been observed that the electron plasma wave is driven more efficiently by a cosh-Gaussian laser beam that accelerates plasma electrons to higher energies.
ISSN:0306-8919
1572-817X
DOI:10.1007/s11082-021-03244-9