Electron injection for enhanced energy gain by a radially polarized laser pulse in vacuum in the presence of magnetic wiggler

Ghotra, Harjit Singh; Kant, Niti

doi:10.1063/1.4939027

Cited by 24 publications

(13 citation statements)

References 25 publications

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“…However, these studies on Thomson scattering seldom address a tightly focused Gaussian laser pulse, whose transverse energy distribution is localized in a small range, and its transverse and longitudinal intensity distribution satisfies the Gaussian envelope [29,30], which is commonly used to describe the laboratory laser systems. It has been shown that for the tightly focused Gaussian laser pulse, the factors such as external magnetic field, chirped laser pulse and laser pulse polarization have significant effects on the electron acceleration [31][32][33]. In this paper, the effects of parameters of the tightly focused Gaussian laser pulses and external magnetic field on the electron dynamics and the radiation spectrum are mainly investigated.…”

mentioning

confidence: 99%

Enhanced radiation of nonlinear Thomson backscattering by a tightly focused Gaussian laser pulse and an external magnetic field

Hong¹,

Wei²,

Li³

et al. 2022

EPL

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The electron dynamics and the Thomson backscattering of an electron moving in a combined field of a tightly focused Gaussian laser pulse and an external uniform magnetic field are investigated in detail. It is found that by considering the tightly focused Gaussian laser pulse, the electron can be pushed out from the laser pulse by the ponderomotive force, resulting in the symmetry breaking of the electron dynamics from the Gaussian envelope, which can dramatically enhance the radiation intensity. It is also found that by introducing an external magnetic field, the emergence of the cyclotron motion of the electron under the external magnetic field also breaks the symmetry of the electron dynamics and enhances the radiation. Especially in the resonance case, i.e., the cyclotron frequency of the electron is close to the laser frequency, the emission spectrum is further enhanced due to the great extension of the interaction time and the symmetry breaking by the beat wave between the helix motion and the cyclotron motion of the electron in the combined field, and a platform with high radiation intensity containing the THz band has also appeared.

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confidence: 99%

Enhanced radiation of nonlinear Thomson backscattering by a tightly focused Gaussian laser pulse and an external magnetic field

Hong¹,

Wei²,

Li³

et al. 2022

EPL

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“…Polarization characteristics also play a crucial role in transferring energy on laser driven charged particle acceleration. Better trapping has been investigated in case of radially polarized (RP) laser pulse [22]. It has also been noticed that higher energy gain occurs when we employ circularly polarized (CP) laser pulse in comparison with others [23].…”

Section: Introductionmentioning

confidence: 99%

Comparison of different laser pulse envelopes with frequency chirp for efficient electron acceleration in vacuum

Pramanik

Ghotra

Kant

et al. 2022

J. Phys.: Conf. Ser.

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In the present manuscript, we have investigated the effect of chirped laser pulse envelope to study electron acceleration in vacuum. For this purpose, we have chosen two different pulse shapes, i.e trapezoidal pulse envelope and Sin4 pulse envelope. Electron has been injected axially to the front of the tested envelopes. In all calculations, the front end of each pulse is presumed to have caught up with the electron at t = 0 at the coordinate origin. The relativistic Newton-Lorentz equations of motion of electron in the field of the laser pulse have been analytically and numerically solved. By optimizing laser and frequency chirp parameters, the energy gain of the order of GeV is obtained, and it has been noticed that under the similar range of phases (0 to 2π) and laser intensity parameter (a0 = 3), trapezoidal pulse envelope shows better result than Sin4 pulse envelope on effective electron acceleration in vacuum.

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“…In addition, the effect of chirped laser pulse and magnetic field interaction in the IFEL acceleration scheme was investigated and they showed how tightly focused chirped-pulse enhances the energy from MeV to GeV [30]. In other work, how magnetic wiggler perpetuates the resonance of betatron and enhances the energy gain (up to 4 times more) is shown [31].…”

Section: Introductionmentioning

confidence: 99%

Electron acceleration in an inverse free electron laser with a tapered wiggler field

Singh

Rajput

Kant

et al. 2022

J. Phys.: Conf. Ser.

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Numerical study of inverse free-electron laser acceleration (IFELA) in the presence of a tightly focused laser beam is investigated in vacuum. In this article, we investigate the dynamics of an electron in the inverse free-electron laser (IFEL) with a planer wiggler field geometry. The numerical study on particle acceleration is carried out for tightly focused laser parameters as well as the tapering along the wiggler field. It is observed that the effect of tapering point along the undulator is crucial to maintain the IFEL resonance condition and to maximize the energy gain. The role of normalized laser field and of tapering point of planar wiggler magnetic field is examined on the electron acceleration. The role of pre-energy modulation of real electron-bunch and its acceleration will be planned in our next simulation work.

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Electron injection for enhanced energy gain by a radially polarized laser pulse in vacuum in the presence of magnetic wiggler

Cited by 24 publications

References 25 publications

Enhanced radiation of nonlinear Thomson backscattering by a tightly focused Gaussian laser pulse and an external magnetic field

Enhanced radiation of nonlinear Thomson backscattering by a tightly focused Gaussian laser pulse and an external magnetic field

Comparison of different laser pulse envelopes with frequency chirp for efficient electron acceleration in vacuum

Electron acceleration in an inverse free electron laser with a tapered wiggler field

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