KWANG MIN YU

Type

Text

Type

Dissertation

Advisor

Samulyak, Roman V | Glimm, James | Jiao, Xiangmin | Lin, Meifeng.

Date

2016-12-01

Keywords

Computational Electrodynamics, Numerical Simulation, Particle Accelerator, Particle-in-Cell | Applied mathematics

Department

Department of Applied Mathematics and Statistics

Language

en_US

Source

This work is sponsored by the Stony Brook University Graduate School in compliance with the requirements for completion of degree.

Identifier

http://hdl.handle.net/11401/77366

Publisher

The Graduate School, Stony Brook University: Stony Brook, NY.

Format

application/pdf

Abstract

A parallel, fully relativistic, 3D electromagnetic particle-in-cell (EM-PIC) code, named SPACE, has been developed for the simulation of relativistic particle beams, beam - plasma interaction, and plasma chemistry. New algorithms such as atomic processes in plasma, proper boundary conditions, and an efficient method for highly-relativistic beams in non-relativistic plasma have been developed. Algorithms for atomic process include ionization of neutral atoms by electron impact, recombination of plasma, and electron attachment on dopants in dense neutral gases. The code has been used for the simulation of processes in high-pressure radio-frequency (RF) cavity (HPRF) program at Fermilab. Advanced numerical simulations resolve all physically relevant processes in RF cavity filled with high-pressure gases and interacting with proton beams. Simulations also support broader research on the design of muon cooling devices. From simulation studies of microphysics processes, macroscopic and experimentally measurable quantities have been derived. Through comparison with experiments in the MTA, simulations quantified several uncertain values of plasma properties such as effective recombination rates and the attachment time of electrons to dopant molecules. Simulations have achieved very good agreement with experiments on plasma loading and related processes. The experimentally validated code SPACE will be used for simulations of muon cooling devices in regimes beyond current experimental capabilities. In addition, the code is used to study advanced coherent electron cooling (ACeC) for the e-RHIC project at BNL. Simulations study the modulation effect of highly relativistic ions of gold on co-propagating electron plasma and the amplification of modulation. Parallel simulations were able to track every real electron in physically relevant domains. | 131 pages

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