Emittance growth and halo formation in the relaxation of mismatched beams
Abstract
In this paper, a simplified theoretical model that allows prediction of the final stationary state attained by an initially mismatched beam is presented. The proposed stationary state has a core-halo distribution. Based on the incompressibility of the Vlasov phase-space dynamics, the core behaves as a completely degenerate Fermi gas, where the particles occupy the lowest possible energy states accessible to them. On the other hand, the halo is given by a tenuous uniform distribution that extends up to a maximum energy determined by the core-particle resonance. This leads to a self-consistent model in which the beam density and self-fields can be determined analytically. The theory allows one to estimate the emittance growth and the fraction of particles that evaporate to the halo in the relaxation process. Self-consistent N-particle simulation results are also presented and are used to verify the theory.
- Publication:
-
Physical Review Accelerators and Beams
- Pub Date:
- November 2010
- DOI:
- Bibcode:
- 2010PhRvS..13k4202T
- Keywords:
-
- 41.85.Ja;
- 41.75.-i;
- 05.70.Ln;
- Beam transport;
- Charged-particle beams;
- Nonequilibrium and irreversible thermodynamics