A high-energy electron density modulator driven by an intense laser standing wave

AbstractA high energy electron density modulator from a high-intensity laser standing wave field is studied herein by investigating the ultrafast motion of electrons in the field. Electrons converge at the electric field antinodes, and the discrete electron density peaks modulated by the field located at the corresponding laser phases of kx = nπ, (n = 0, 1, 2, …), that is, the modulation period is 1/2 the wavelength of the individual laser. We also discussed the influence of the laser parameters such as laser intensity and waist size on the beam modulator. It is shown that a long interaction length (waist) or sufficiently high field intensity is essential for relativistic electron density modulation.

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Radiation characteristics of single and double peak pulses produced by a high energy electron head-on colliding with an intense laser pulse

10.1117/12.2600888 ◽

2021 ◽

Author(s):

Yu Chen ◽

Hui Liu ◽

Yunfeng Cai ◽

Youwei Tian

Keyword(s):

Laser Pulse ◽

High Energy ◽

Energy Electron ◽

Intense Laser ◽

High Energy Electron ◽

Intense Laser Pulse ◽

Radiation Characteristics ◽

Double Peak

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Recent Progress of High Energy Electron Generation in Intense Laser-Plasma Interactions in Institute of Physics, Chinese Academy of Sciences

2007 Conference on Lasers and Electro-Optics - Pacific Rim ◽

10.1109/cleopr.2007.4391148 ◽

2007 ◽

Author(s):

Yutong Li ◽

Zhengming Sheng ◽

Zhiyin Wei ◽

Jie Zhang

Keyword(s):

Laser Plasma ◽

Recent Progress ◽

High Energy ◽

Energy Electron ◽

Intense Laser ◽

High Energy Electron ◽

Laser Plasma Interactions ◽

Electron Generation ◽

Chinese Academy Of Sciences ◽

Academy Of Sciences

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COMPUTATIONAL THEORY OF REFLECTION HIGH ENERGY ELECTRON DIFFRACTION

Surface Review and Letters ◽

10.1142/s0218625x97000493 ◽

1997 ◽

Vol 04 (03) ◽

pp. 513-524 ◽

Cited By ~ 14

Author(s):

P. A. MAKSYM

Keyword(s):

Electron Diffraction ◽

High Energy ◽

Energy Electron ◽

Alternative Methods ◽

Computational Techniques ◽

Computational Technique ◽

High Energy Electron ◽

Crystal Surfaces ◽

Computational Theory ◽

The Individual

The theory of reflection high energy electron diffraction (RHEED) by crystal surfaces is reviewed, with special emphasis on computational techniques. Multiple scattering is accounted for by solving the Schrödinger equation exactly to obtain the amplitudes of the diffracted beams above the surface. The surface and substrate are divided into atomic layers and the RHEED intensities for the entire system are determined from the scattering properties of the individual layers. Alternative methods for implementing this approach are explained and compared. Recent applications to analysis of real RHEED data are used to illustrate the general theory and it is shown that it can provide very good agreement with experiment. The computational efficiency of RHEED calculations is examined carefully and key bottlenecks are identified. This leads to a new computational technique which is much faster than existing ones. Some problems connected with the implementation of this approach are examined in detail.

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