Theories and Particle-In-Cell Simulations of Emittance Growth Due to Coulomb Collision in Plasma-based Accelerators

Yinjian Zhao; Remi Lehe; Andrew Myers; Maxence Thevenet; Axel Huebl; Carl Schroeder; Jean-Luc Vay

Theories and Particle-In-Cell Simulations of Emittance Growth Due to Coulomb Collision in Plasma-based Accelerators

ORAL

Abstract

In plasma-based accelerators, a crucial requirement for many applications is to keep the beam emittance from degrading. One source of emittance degradation is through Coulomb collision. This paper shows that the emittance growth due to Coulomb collision can be correctly captured in particle-in-cell simulations, with a proper Monte Carlo binary collision module implemented. In addition, the theory of the emittance growth due to Coulomb collision is extended from a monoenergetic matched beam to a mismatched beam with energy spread.

Nov. 10, 2020, 3:12 PM – Nov. 10, 2020, 3:24 PM

Authors

Yinjian Zhao

Lawrence Berkeley National Laboratory
Remi Lehe

LBNL, Lawrence Berkeley National Laboratory
Andrew Myers

Lawrence Berkeley National Laboratory
Maxence Thevenet

Lawrence Berkeley National Laboratory
Axel Huebl

LBNL, previously HZDR, Lawrence Berkeley National Laboratory
Carl Schroeder

Lawrence Berkeley National Laboratory, UCB; LBNL, Berkeley National Laboratory, BELLA Center, Lawrence Berkeley National Laboratory
Jean-Luc Vay

LBNL, Lawrence Berkeley National Laboratory