PAC2013 - List of Authors (Fiorito, R.B.)

Paper

Title

Page

New Technique to Measure the Emittance of Beams with Space Charge

931

K. Poor Řežaei, R.B. Fiorito, R.A. Kishek
UMD, College Park, Maryland, USA

Funding: Work funded by the US Dept. of Energy Office of High Energy Physics and the US Dept. of Defense Office of Naval Research and Joint Technology Office.
Characterization of the transverse phase space of electron beams with space charge is an important requirement for high brightness particle accelerators. We present a novel technique to measure the transverse rms emittance. The method uses the beam divergence, measured, e.g. with optical transition radiation interferometry*, and the beam radius, obtained by imaging the beam, to determine the cross correlation term and thus all the terms in the equation for the rms emittance. The experimental data is obtained with a lens-drift-screen setup similar to what is used in a quadrupole scan. However, the analysis of the scan data is unique. It involves taking the cross-correlation term as a control variable in a procedure which matches the beam envelop radius and its derivative calculated from the envelope equation, with the measured radius and divergences at the screen. A linear space charge model is used in the envelope equations, hence the errors in the measurement relate to the nonuniformity of the beam transverse distribution. The technique is tested using simulated data.
* R. B. Fiorito, et al., “Interference of diffraction and transition radiation and its application as a beam divergence diagnostic,” Phys. Rev. ST Accel. Beams, Vol. 9, pp. 052802, (2006).

FROAA1

The University of Maryland Electron Ring (UMER) Program - Recent Developments

R.A. Kishek, B.L. Beaudoin, S. Bernal, M. Cornacchia, D.W. Feldman, R.B. Fiorito, I. Haber, T.W. Koeth, Y. Mo, K. Poor Řežaei, K.J. Ruisard, W.D. Stem, D.F. Sutter, H.D. Zhang
UMD, College Park, Maryland, USA

Funding: Supported by the US Dept. of Energy, Office of High Energy Physics, and by the US Dept. of Defense, Office of Naval Research and the Joint Technology Office.
Space charge, especially in the beam source and low energy regions, can substantially impact the dynamics of advanced accelerators at the intensity frontier. UMER uses scaled electron beams at nonrelativistic energies (10 keV) to inexpensively access the intense space charge dynamics directly relevant to low-energy hadron and ion beams, in both rings and linacs. In UMER, space charge tune depressions at injection are adjustable in the range of 0.14 - 0.8, enabling scaled examination of a wide range of phenomena. Longitudinal induction focusing is used to counteract the space charge force at the edges of a long rectangular bunch, confining it for 100s of turns. This paper reviews recent experimental, computational, and theoretical research on UMER. Specific topics include longitudinal induction bunch-end focusing; generation and propagation of longitudinal space charge waves, including large-amplitude solitons; bunch end interpenetration and observation of a resulting multi-stream instability; beam halo studies; beam current-dependence of classical ring parameters (natural chromaticity, lattice dispersion and momentum compaction); and diagnostic development.

Slides FROAA1 [5.696 MB]

Paper	Title	Page
WEPBA20	New Technique to Measure the Emittance of Beams with Space Charge	931
	K. Poor Řežaei, R.B. Fiorito, R.A. Kishek UMD, College Park, Maryland, USA
	Funding: Work funded by the US Dept. of Energy Office of High Energy Physics and the US Dept. of Defense Office of Naval Research and Joint Technology Office. Characterization of the transverse phase space of electron beams with space charge is an important requirement for high brightness particle accelerators. We present a novel technique to measure the transverse rms emittance. The method uses the beam divergence, measured, e.g. with optical transition radiation interferometry, and the beam radius, obtained by imaging the beam, to determine the cross correlation term and thus all the terms in the equation for the rms emittance. The experimental data is obtained with a lens-drift-screen setup similar to what is used in a quadrupole scan. However, the analysis of the scan data is unique. It involves taking the cross-correlation term as a control variable in a procedure which matches the beam envelop radius and its derivative calculated from the envelope equation, with the measured radius and divergences at the screen. A linear space charge model is used in the envelope equations, hence the errors in the measurement relate to the nonuniformity of the beam transverse distribution. The technique is tested using simulated data. R. B. Fiorito, et al., “Interference of diffraction and transition radiation and its application as a beam divergence diagnostic,” Phys. Rev. ST Accel. Beams, Vol. 9, pp. 052802, (2006).

FROAA1	The University of Maryland Electron Ring (UMER) Program - Recent Developments
	R.A. Kishek, B.L. Beaudoin, S. Bernal, M. Cornacchia, D.W. Feldman, R.B. Fiorito, I. Haber, T.W. Koeth, Y. Mo, K. Poor Řežaei, K.J. Ruisard, W.D. Stem, D.F. Sutter, H.D. Zhang UMD, College Park, Maryland, USA
	Funding: Supported by the US Dept. of Energy, Office of High Energy Physics, and by the US Dept. of Defense, Office of Naval Research and the Joint Technology Office. Space charge, especially in the beam source and low energy regions, can substantially impact the dynamics of advanced accelerators at the intensity frontier. UMER uses scaled electron beams at nonrelativistic energies (10 keV) to inexpensively access the intense space charge dynamics directly relevant to low-energy hadron and ion beams, in both rings and linacs. In UMER, space charge tune depressions at injection are adjustable in the range of 0.14 - 0.8, enabling scaled examination of a wide range of phenomena. Longitudinal induction focusing is used to counteract the space charge force at the edges of a long rectangular bunch, confining it for 100s of turns. This paper reviews recent experimental, computational, and theoretical research on UMER. Specific topics include longitudinal induction bunch-end focusing; generation and propagation of longitudinal space charge waves, including large-amplitude solitons; bunch end interpenetration and observation of a resulting multi-stream instability; beam halo studies; beam current-dependence of classical ring parameters (natural chromaticity, lattice dispersion and momentum compaction); and diagnostic development.
	Slides FROAA1 [5.696 MB]