Plasma Dark Current in Plasma Wake Field Accelerators (PWFA)

Erdem Oz; Tom Katsouleas; Patric Muggli; Christopher Barnes; Franz Josef Decker; Paul J. Emma; Mark J. Hogan; Rasmus Ischebeck; Devon K. Johnson; Chris Clayton; Richard H. Iverson; Wei Lu; Robert H. Siemann; Chan Joshi; Warren Mori; Dieter Walz; Ken Marsh; Chengkun Huang; Patrick Krejcik; Miaomiao Zhou; Caolionn O&#039;Connell; Suzhi Deng

Plasma Dark Current in Plasma Wake Field Accelerators (PWFA)

POSTER

Abstract

Evidence of particle trapping has been observed in a beam driven Plasma Wake Field Accelerator (PWFA) experiment, E164X, conducted at the Stanford Linear Accelerator Center. Trapped electrons are observed when the wake field amplitude is above a certain threshold. Trapped electrons in plasma accelerators are the equivalent of the dark current in RF accelerators. Calculations show that the trapping threshold is lower in the case of a plasma field ionized by the electron bunch itself than in a pre-ionized plasma. Experimental and simulation results will be presented.

Authors

Erdem Oz
Tom Katsouleas

University of Southern California
Patric Muggli

USC
Christopher Barnes
Franz Josef Decker
Paul J. Emma
Mark J. Hogan
Rasmus Ischebeck

Stanford Linear Accelerator Center, SLAC
Devon K. Johnson
Chris Clayton

UCLA
Richard H. Iverson

SLAC
Wei Lu

UCLA
Robert H. Siemann
Chan Joshi

SLAC
Warren Mori

UCLA, University of California Los Angeles, CA 90095, U.S.A., Department of Physics and Astronomy and Electrical Engineering, UCLA, Los Angeles, California 90095, USA
Dieter Walz

SLAC
Ken Marsh
Chengkun Huang

UCLA
Patrick Krejcik

SLAC
Miaomiao Zhou

UCLA
Caolionn O'Connell

SLAC
Suzhi Deng

USC