Particle-In-Cell Modeling of Plasma-Based Accelerators in Two and Three Dimensions

TL;DR

This dissertation presents a comprehensive Particle-In-Cell simulation code for plasma-based accelerators, providing insights into laser-plasma interactions, electron injection, and wakefield acceleration, supporting experimental and theoretical advancements.

Contribution

Developed a fully object-oriented, relativistic multi-dimensional Particle-In-Cell code and applied it to key plasma accelerator research questions, including electron injection and wakefield dynamics.

Findings

Electron injection via transversely propagating laser pulses is feasible.

Laser-guided wakefield acceleration can extend beyond Rayleigh length.

Nonlinear blowout regime simulations reveal complex plasma wake dynamics.

Abstract

In this dissertation, a fully object-oriented, fully relativistic, multi-dimensional Particle-In-Cell code was developed and applied to answer key questions in plasma-based accelerator research. The simulations increase the understanding of the processes in laser plasma and beam-plasma interaction, allow for comparison with experiments, and motivate the development of theoretical models. The simulations support the idea that the injection of electrons in a plasma wave by using a transversely propagating laser pulse is possible. The beam parameters of the injected electrons found in the simulations compare reasonably with beams produced by conventional methods and therefore laser injection is an interesting concept for future plasma-based accelerators. Simulations of the optical guiding of a laser wakefield driver in a parabolic plasma channel support the idea that electrons can be accelerated over distances much longer than the Rayleigh length in a channel. Simulations of plasma wakefield acceleration in the nonlinear blowout regime give a detailed picture of of the highly nonlinear processes involved. Using OSIRIS, we have also been able to perform full scale simulations of the E-157 experiment at the Stanford Linear Accelerator Center. These simulations have aided the experimentalists and they have assisted in the development of a theoretical model that is able to reproduce some important aspects of the full PIC simulations. Update (2015): This dissertation was originally written in 2000. I am making it now available on arXiv with the hope that some its content might proof useful to the users of the OSIRIS code which has continued to be utilized by a number of research groups since it was originally written as part of the research presented in this dissertation.