IPAC'10 - List of Authors (Cousineau, S.M.)

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Cousineau, S.M.

Paper	Title	Page
TUPD073	Effect of Bunch Shape on Electron-Proton Instability	2090
	Z. Liu IUCF, Bloomington, Indiana S.M. Cousineau, V.V. Danilov, J. Galambos, J.A. Holmes, M.A. Plum ORNL, Oak Ridge, Tennessee
	The instability caused by the electron cloud effect (ECE) may set an upper limit to beam intensity in proton storage rings. This instability is potentially a major obstacle to the full intensity operation, at 1.5·10¹⁴ protons per pulse, of the Spallation Neutron Source (SNS). High intensity experiments have been done with different sets of parameters that affect the electron-proton (e-p) instability, of which bunch intensity and bunch shape are considered as two main factors. In the experiment, the phase and amplitude of the second harmonic RF cavity are used to modify the bunch shape. Simulation with the beam dynamics code ORBIT has been carried out to compare with experimental results and to understand the impact of bunch shape on electron cloud build-up and beam stability. We have also attempted to benchmark the e-p model to predict the frequency spectrum and the RF buncher voltage threshold values against experimental results. Details and discussion will be reported in this conference. * M.T.F. Pivi and M.A. Furman, PRSTAB 6, 034201 (2003) V. Danilov et. al, 39th ICFA Advanced Beam Dynamics Workshop, 2006 * B. Macek et. al, PAC 2003

Paper

Title

Page

TUPD073

Effect of Bunch Shape on Electron-Proton Instability

2090

Z. Liu
IUCF, Bloomington, Indiana
S.M. Cousineau, V.V. Danilov, J. Galambos, J.A. Holmes, M.A. Plum
ORNL, Oak Ridge, Tennessee

The instability caused by the electron cloud effect (ECE) may set an upper limit to beam intensity in proton storage rings. This instability is potentially a major obstacle to the full intensity operation, at 1.5·10¹⁴ protons per pulse, of the Spallation Neutron Source (SNS). High intensity experiments have been done with different sets of parameters that affect the electron-proton (e-p) instability, of which bunch intensity and bunch shape are considered as two main factors. In the experiment, the phase and amplitude of the second harmonic RF cavity are used to modify the bunch shape. Simulation with the beam dynamics code ORBIT has been carried out to compare with experimental results and to understand the impact of bunch shape on electron cloud build-up and beam stability. We have also attempted to benchmark the e-p model to predict the frequency spectrum and the RF buncher voltage threshold values against experimental results. Details and discussion will be reported in this conference.

* M.T.F. Pivi and M.A. Furman, PRSTAB 6, 034201 (2003)
** V. Danilov et. al, 39th ICFA Advanced Beam Dynamics Workshop, 2006
*** B. Macek et. al, PAC 2003