Transcript MIniphase

Injector Setup/Mini-phase
Stephen Benson, JLab
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Description of injector setup
sources of drift
Mini-phase procedure for injector
Checking the rest of the machine.
Gun Setup
Beam parameters that need to be set in the injector:
 Drive laser parameters: Set pulse length using autocorrelator, set transverse
profile using Brewster window camera, and set position on cathode using cathode
camera. Set power using Unser monitor or 1G dump Faraday cup.
 Gun voltage. Set open loop.
 Magnets. 14 correctors and 8 focusing elements. Center in some focusing
elements. Dipole bus set for 9 MeV energy.
 RF gradients and phases. Spectrometer phasing and gradient setup at first,
then use 1st cavity focusing, second cavity gradient, and energy spread from
injector. Don’t know how to set the laser vs. buncher phase or buncher gradient.
 Match to linac to set quads. Use spreadsheet model and iterate.
Once the injector is setup, only change the phases and cavity 3 gradient and maintain
laser state.
Reminder of Injector Geometry
SRF cavities (2)
Solenoids (2)
Electron gun (1)
Viewers (3)
Quads (4)
Injector / Drive Laser Diagnostics
 all focusing elements are placed upstream of the pick off plate
 distance from the pick off to the cathode = distance from pick off to reference screen
 the reference screen used for D.L. profile and position measurements
Injector / Drive Laser Diagnostics
Typical auto-correlator signal JLab FEL D.L.
(observed in the control room permanently)
Drive Laser transverse profile
dynamic range ~500:
10-bit frame grabber,
60 dB SNR CCD
Drive Laser “ghost” pulses
 If “ghost” pulses get large they can effect the beam images and throw you.
Problem:
 this does not work
for CW beam
Beam current measurements
with a linear circuit
current measurements with
A Log-amp circuit (60 dB)
Magnetic Elements
There are 23 magnetic elements in the injector. The MBH0F06H
is almost always zero, as is the MQZ0F02. Not shown are the
injector string. Note the strengths of the magnets before the unit.
Use 0F01 to set position in the buncher, 0F01A to center in 2nd
solenoid, 0F02 to “center” in the unit 0F03 to center in MQJ0F05,
0F05 to center in MPJ0F06, 0F06V to center vertically at
ITV0F06 and 0F06A to center in the ITV0F01 hole.
Never change magnets during a miniphase!
Injector Phase Monitor
Multiplexer
Laser
Cathode
Buncher
Vector
Voltmeter
Phasing the Injector
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Once beam is steered up before the cryounit, zero the
buncher GASK signal using the drive laser phase.
Obtain reasonable spots on ITV0F04 and ITV0F06
using laser/buncher gang phase and cavity 3 phase.
Use injector phasing script to set laser/buncher gang
phase and cavity 3 phase.
Check centering in the unit and last two quads.
Set cavity 3 gradient to center the beam at ITV0F06.
Check Happek. If low, reoptimize using laser phase
and buncher gradient. If you have to change these, go
back to the beginning and iterate.
Record miniphase images and phases.
Injector / Transverse beam profile
 ITV0F04 image is sensitive to cavity 4 phase (size) and cavity 3 phase (x-position)
 ITV0F06 image is sensitive to cryounit gradients, cavity 3 phase (x-position)cavity 4 phase, vertical size,
and laser phase (horizontal size)
 Phases drift more and faster than gradients. Also get small drift in vertical steering.
Pulsed and CW beam measurements / transition
Interferogram
(autocorrelation)
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Most affordable way to measure ps and
sub-ps bunches
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Works with pulsed beam (tune up) and CW
beam, essentially at any average current
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Used at JLab FEL to ensure that the bunch
length does not change for pulsed or CW
and when the average current is increased
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Ultimately needs to be setup in vacuum (or
N2 purge) due to atmosphere absorption of
THz
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Phase information is lost – no direct bunch
profile reconstruction
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A detector measuring total CTR (CSR)
power – a bunch length monitor
Power spectrum
Conclusion
 Setup of injector is moderately complicated but straightforward. It can take
several hours to a couple days and can change every corrector and RF
parameter in the injector.
 One the injector is setup, images are taken of ITV0F04 and ITV0F06. If
these are reproduced in practice, the beam is also reproduced. Only phases
are changed.
 Linac phasing establishes beam 10 degrees off crest in the linac.
 Vernier cavity is used to adjust the longitudinal match. Verified using Happek
scan
 Path Length corrector does not reproduce. It must be checked each time the
machine is started up.
 Steering of the second pass at 5F10 might be possible if losses are found in
the linac.
Note: The Path length and 5F10 correctors are the only allowed correctors.
Not quads can be changed in a miniphase.