Title :
Modeling single-frequency laser-plasma acceleration using particle-in-cell simulations: the physics of beam breakup
Author :
Decker, C.D. ; Mori, Warren B. ; Tzeng, Kuo-Cheng ; Katsouleas, Thomas C.
Author_Institution :
Lawrence Livermore Nat. Lab., CA, USA
fDate :
4/1/1996 12:00:00 AM
Abstract :
We investigate electron acceleration from space-charge waves driven by single-frequency lasers using a fully explicit particle-in-cell (PIC) model. The two dimensional (2-D) simulations model ~100 fs pulses at densities near n=4×1019 cm-3 for 1-μm lasers. The pulses are found to break up due to a combination of longitudinal and transverse bunching of the laser intensity via Raman forward scattering type instabilities. The ponderomotive force of these intensity modulations generates large amplitude plasma waves. Large numbers of self-trapped electrons and multiple Raman forward scattering satellites are observed. The relevance of these simulations to experiments is discussed
Keywords :
Raman spectra; beam handling techniques; collective accelerators; electron accelerators; plasma instability; plasma simulation; plasma waves; space charge waves; 1 mum; 100 fs; 2D simulations; Raman forward scattering type instabilities; beam breakup physics; electron acceleration; intensity modulations; large amplitude plasma waves; laser intensity; longitudinal bunching; multiple Raman forward scattering satellites; particle-in-cell simulations; ponderomotive force; self-trapped electrons; single-frequency laser-plasma acceleration modeling; single-frequency lasers; space-charge waves; transverse bunching; Acceleration; Electrons; Intensity modulation; Laser modes; Optical pulses; Particle scattering; Plasma waves; Raman scattering; Satellites; Two dimensional displays;
Journal_Title :
Plasma Science, IEEE Transactions on
