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BEAM STUDIES AT THE SNS LINAC. Yan Zhang On behalf of the SNS team. 42nd ICFA, HB2008, Nashville, USA, August 25-29, 2008. Outline. Introduction to the SNS Linac Longitudinal Beam Dynamics Studies Transverse Beam Dynamics Studies Unsolved Puzzles Summary. The SNS Linac. To Ring. - PowerPoint PPT Presentation
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Managed by UT-Battellefor the Department of Energy
BEAM STUDIES AT THE SNS LINAC
Yan Zhang
On behalf of the SNS team
42nd ICFA, HB2008, Nashville, USA, August 25-29, 2008
2 Managed by UT-Battellefor the Department of Energy Presentation_name
Outline
Introduction to the SNS Linac Longitudinal Beam Dynamics Studies Transverse Beam Dynamics Studies Unsolved Puzzles Summary
3 Managed by UT-Battellefor the Department of Energy Presentation_name
The SNS Linac
Injector 2.5 MeV
RFQ
1 GeV=0.87
DTL
86.8 MeV
To Ring
CCL
402.5 MHz 805 MHz
SCL, ß=0.61
186 MeV=0.55
HEBTMEBT SCL, ß=0.81
391 MeV=0.71
Linac dump
Length ~260 m, 96 independently phased RF cavity/tanks
Normal conducting linac from the H- ion source to 186 MeV
Superconducting linac from 186 MeV to 1 GeV Beam commissioning of the SCL began in August 2005 Achieved the design repetition rate 60 Hz, maximum beam energy 1.01 GeV, peak beam current 40 mA, pulse length 1 ms, beam power on the mercury target 520 kW.
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RMS phase in the warm linac, linear map and zero current
Longitudinal Lattice
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Phase oscillation in one of the SCL commissioning lattice
Y. Zhang, S. Henderson, this proceedings.
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Longitudinal beam emittance increase in the SCL commissioning lattice
0.2
0.3
0.4
0.5
0.6
0 50 100 150 200z (m)
emit.
(mm
*mra
d)
xyzxyz
baseline
commission
IMPACT, beam current 20 mA
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Beam phase oscillation and damping are sensitive to RF errors
Y. Zhang, et. al., NIM B 261 (2007)
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SCL phase oscillation measured in February 2006
First cavity gradient 10% & 15% reduction, model & measurement
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A. V. Aleksandrov, et. al., EPAC2008
RF Shaker, warm linac model prediction and BPM measurement
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SCL phase oscillation, dominated by random errors (~2 phase, ~2% amplitude) and likely caused by RF driftings
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Longitudinal Beam Emittance Measurement
A. V. Feschenko, et. al., PAC2007
Beam phase profile measured with a BSM in CCL1
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Y. Zhang, et. al., submitted to PRST-AB
Model predicted the SCL longitudinal acceptance
BCM measured acceptance
SCL longitudinal acceptance measurement with BCM and BLMs
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Bunch shape measurement
Energy profile measurement
Bunch shape and beam energy profile measured with BCM
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Cav_01a reference phase set at -85, -90 and -95 degree
Longitudinal beam contours at the SCL entrance (Cav_01b) RMS emittance: 2.9 MeV*deg ~ 2.2 times the nominal design
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12/23/2007
Phase tails
> 40 deg
06/15/2008
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12/23/2007
Energy tails
> 3 MeV
06/15/2008
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Transverse Beam Dynamics
Multiple wire scans measure beam profiles, and fit the measured beam RMS size with the accelerator models
•On-line model in the XAL is based on TRACE3D.
•Transverse – longitudinal phase space coupling.
•Higher order effects: emittance growth in RF gaps, chromatic aberrations in “short” quadrupoles.
Beam emittance and twiss parameter measurement at MEBT
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Y. Zhang, J. Qiang, this proceedings
MEBT beam parameter measurement using the IMPACT model
19 Managed by UT-Battellefor the Department of Energy Presentation_name
Beam Trajectory Correction
Warm Linac
SCL
T. Pelaia, et. al., ICALEPCS 2007
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A. Shishlo, A. V. Aleksandrov, EPAC2008
Before quads shaker
After quads shaker - model based alignment
x
Y
x
Y
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Linac residual activations after neutron productions
Unsolved Puzzles
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SCL Acceptance, MEBT Particles and CCL Particles
SCL Longitudinal Acceptance and …
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Longitudinal emittance in the warm linac
The nc. linac could be a halo filter (scrapper) if no error existed
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Beam loss in the linac, No Error, RF Error, MEBT RBs gradients
RFQ Beam Tails plus Linac RF Errors ?
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Beam Loss In the SNS Linac (500 kW)
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Partially chopped beams ?
CCL1 BPM amplitude and phase measurement for 4 mini-pulse
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Increase the SCL acceptance ?
s = -35 (design: -20), sacrifices ~100 MeV output energy
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Summary Beam dynamics studies at the SNS linac are performed with
several conventional and newly developed techniques. Beam longitudinal tails/halo shown in the measurements, but
the exact cause of the longitudinal halo is not fully understood. Simulation study of halo in the linac does not have a complete
picture, might need 3D particle tracking from the ion source. Characterize beam halo in the order of 10-5 to 10-4 and reduce
the fractional beam loss to below 10-4 in the SCL is a challenge, existing problems should be fixed first. E.g., MEBT rebuncher, LEBT and MEBT beam chopper, performance of the RFQ, and transverse beam matching through the entire linac correctly…
Beam loss in the linac especially in the SC linac is one of the major concerns to further ramp up the beam power, a factor of two to three beam loss reduction is needed. Suggestions and ideas are welcome.