Title :
Self-injected laser wakefield acceleration in tapered plasma densities
Author :
Suk, H. ; Kim, G.H. ; Kim, J.U. ; Lee, H.J.
Author_Institution :
Center for Adv. Accel., KERI, Changwon, South Korea
Abstract :
Extremely strong electric fields generated by relativistic plasma waves can be used to accelerate electrons to high energy. This can be done either by external injection or self-injection of plasma electrons. In this paper, we report that plasma electrons by the self-injected laser wakefield acceleration using a sharp density transition can gain significantly higher energies when the trapped particles are accelerated in a tapered plasma density. Two-dimensional (2-D) simulation studies show that significantly higher energies can be obtained with an increasing plasma density although space-charge effect of the trapped electrons deforms and deteriorates the laser wakefield severely.
Keywords :
electron traps; plasma accelerators; plasma density; plasma simulation; plasma waves; relativistic plasmas; space charge; wakefield accelerators; electric field generation; electron acceleration; external injection; plasma electrons; plasma waves; self injected laser wakefield acceleration; sharp density transition; space charge effect; tapered plasma density; two dimensional simulation; Acceleration; Electron accelerators; Electron traps; Laser transitions; Optical propagation; Optical pulses; Plasma accelerators; Plasma density; Plasma simulation; Plasma waves;
Conference_Titel :
Vacuum Electronics, 2003 4th IEEE International Conference on
Print_ISBN :
0-7803-7699-4
DOI :
10.1109/IVEC.2003.1286321
