Title :
Optical guiding and electron acceleration in the laser wakefield accelerator
Author :
Sprangle, P. ; Esarey, E. ; Krall, J. ; Joyce, G. ; Ting, A.
Author_Institution :
Plasma Phys. Div., Naval Res. Lab., Washington, DC, USA
Abstract :
The laser wakefield acceleration concept is studied using a general 2D formulation based on relativistic fluid equations. Simulations of an intense laser pulse propagating in a plasma address both optical guiding and wakefield generation issues. It is shown that relativistic guiding is ineffective in preventing the diffraction of short pulses and long pulses are broken up into beamlet segments due to wakefield effects. The use of preformed plasma density channels or tailored pulse profiles allows intense laser propagation over many Rayleigh lengths. The ponderomotive force associated with the laser pulse envelope generates large amplitude accelerating and focusing wakefields over long distances to achieve electron trapping, acceleration and focusing.
Keywords :
electron accelerators; electron beam focusing; electron traps; plasma density; plasma light propagation; wakefield accelerators; Rayleigh lengths; Wakefield accelerating; Wakefield focusing; beamlet segments; diffraction prevention; electron acceleration; electron focusing; electron trapping; general 2D formulation; laser Wakefield acceleration; optical guiding; plasma laser pulse; ponderomotive force; preformed plasma density channels; relativistic fluid equations; relativistic guiding; tailored pulse profiles; Acceleration; Equations; Laser modes; Mathematical model; Optical diffraction; Optical propagation;
Conference_Titel :
High-Power Particle Beams, 1992 9th International Conference on
Conference_Location :
Washington,DC
Print_ISBN :
000-0-0000-0000-0
