ubw2012, berlin, december 2012 jefferson lab experience with beam halo, beam loss and related beam...
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UBW2012, Berlin, December 2012
Jefferson Lab Experience withBeam Halo, Beam Loss andRelated beam diagnostics
Pavel Evtushenko, Steve Benson, Dave Douglas, Kevin Jordan, Carlos Hernandez-Garcia, Dan Sexton, Jay Benesch, Arne Freyberger
UBW2012, Berlin, December 2012
Outline
1. IR/UV Upgrade (JLab FEL) overview
2. Different sources of unwanted beam
3. Beam dynamics example
4. Drive Laser related remarks
5. Setting up for high current operation
6. Dynamic range of diagnostics
7. Recent LDR measurments
8. CEBAF overview
9. RF trip rate
10. Direct measurements
11. Vacuum “events”
12. Summary
UBW2012, Berlin, December 2012
JLab IR/UV Upgrade
Ebeam 135 MeVBunch charge: 60 pC – UV FEL
135 pC – IR FEL Rep. rate up to 74.85 MHz
25 μJ/pulse in 250–700 nm UV-VIS
120 μJ/pulse in 1-10 μm IR
UBW2012, Berlin, December 2012
Four sorts of the unwanted beams
1. Fraction of the phase space distribution that is far away from the core (due to the beam dynamics)
2. Low charge due to not well attenuated Cathode Laser (ERLs) – but real bunches that have proper timing for acceleration
3. Due to the Cathode and Laser but not properly timed (scattered and reflected light on the cathode and in the DL transport)
4. Field emission: Gun (can be DC or RF), LINAC itself(is accelerated in both directions)
Flavors of Unwanted Beam
5. Actually, there is one more – ions that accumulate in are true CW electron beam, travel in both directions with thermal velocities in side the electron beam, reduce Q.E. of the cathode one really does not want this beam.
UBW2012, Berlin, December 2012
FEL Injector as an example of #1
Measured in JLab FEL injector,local intensity difference of thecore and “halo” is about 300.(500 would measure as well)10-bit frame grabber & a CCDwith 57 dB dynamic range PARMELA simulations of the same setup with 3E5 particles:
X and Y phase spaces, beam profile and its projection showthe halo around the core of about 3E-3.Even in idealized system (simulation) non-linear beamdynamics can lead to formation of halo.
UBW2012, Berlin, December 2012
Using a Log-amp is an easy way to diagnose presence of the “ghost” pulses Log-amps with dynamic range 100 dB are available
631 uA (100%)135 pC x 4.678 MHz
5.7 uA (~0.9 %)4.678 MHz “ghost”pulses
Drive Laser “ghost” pulses
UBW2012, Berlin, December 2012
DL light scattered on photo cathode
Wafer 25 mm diameter
Active area 16 mm diameter
Drive laser 8 mm diameter
Courtesy of C. Hernandez-Garcia
a view of GaAs photo cathode when running beam (probably 6 % duty cycle or 1.5 %)
measured with simple vis. CCD camera
locations of the wafer and active area are knows from the same view, HV off and white light on
we are looking in to a gap between two non-flat mirrors
with a brand new wafer (no heat cleaning) one would not see any light from the DL spot
At least two processes contribute to the generation of scattering centers
Heat cleaning of the cathode (made periodically, every 4-5 re-Cs)
HV breakdowns can result in rather large pits – scattering and field emission
Visible (green) DL preferable over UV
Preserving cathode surface will be very helpful
Get rid of heat cleaning for GaAs (H – cleaning)
UBW2012, Berlin, December 2012
Cathode Laser pulse via streak camera
appears to be close to Gaussian on linear scale; tails not so much Gaussian
the difference from Gaussian distribution is obvious on log scale
realistic (measured) distribution must be used for realistic modeling
especially is the calculations are intended for large dynamic range effects
UBW2012, Berlin, December 2012
High current operation
JLab FEL driver is setup for high current operation in three steps/phases
Most of the measurements are made with low duty cycle beam beam
(this is Step 1 that establishes best RMS setup for FEL performance)
- setting up injector (RF phases and solenoids)
- transverse match
- longitudinal match
Step 2 is to increase the duty cycle, usually to 6 %, and look at
the beam loss, small adjustments in transverse and long. match often are
required; the adjustments must preserve the high performance of the FEL
this is the reason the adjustments have to be small
When beam loss is small enough high average (9 mA) current can be
operated and the long term trends in pressure (vacuum) are used for
Step 3 of machine adjustment, also very small.
UBW2012, Berlin, December 2012
General FEL remarks
1. JLab FEL is a 9 mA average current machine, despite the fact that all four sorts of beam halo are present (9 mA and 135 MeV 1.2 MW)
2. Setting up for high current operation requires time, but has been done routinely
3. To properly (and quickly) deal with first kind of beam halo Large Dynamic Range diagnostics are needed; until then takes time and trail and error, and origins of problems are not well understood (not confirmed by measurements)
4. For Drive Laser transport Brewster angle windows (input and output); essentially light tight beam line; laser transport with spatial filter to mitigate scattering
5. Scattered DL light on the cathode is a reality one has to leave with, i.e., run beam when it is small enough and replace cathode when it is not.
6. Gradient in the LINAC is limited via requirements to keep dose rate below certain level (especially at the wiggler), but also due to other effects the same as at CEBAF (trip rate)
7. Instruments are: Beam Loss Monitors (BLM) of the MPS
Rad.Con. calibrated ionization chambers
Radiation survey just after beam operation ended (for chronic losses)
LDR diagnostics have been developed
UBW2012, Berlin, December 2012
Operation of JLab FEL with high average current requires a compromise (in terms of match) between high peak beam brightness (required by FEL) and very low beam loss
The match is iterative process and often does not converge easily (if at all…)
For the transverse beam profile measurements and transverse match JLab FEL relies heavily on beam imaging (2D distribution) large number of beam viewers
LINAC beams have neither the time nor the mechanism to come to equilibrium(unlike storage rings, which also run high current)
When setting up a high current accelerators with tune-up beam, halo is something invisible (due to the dynamic range of the measurements) during the setup, yet causing a lot of difficulties when trying to run high current
Why large dynamic range diagnostics?
Increase the DR significantly to make the halo measurable visible with tune-up
beam already; measure the phase space distribution with the LDR and use such
information for the match. When DR is large enough no need to separate what is
core and what is halo.
UBW2012, Berlin, December 2012
Imaging Sensor(s) Dynamic Range
The first issue to overcome is the DR of a single imaging sensor
The main principle is to use imaging with 2 or 3 sensors with different effective gain simultaneously and to combine data in one LDR image digitally(single sensor dynamic range 500..1000 if cost is kept reasonable)
From experience (calculations tested by experiments) we know the safe level of beam current/power for a low duty cycle (tune-up) beam
With typical beam size of few hundred μm OTR signal is attenuated by ~ 10 to keep CCD from saturation. For phosphor or YAG:Ce viewers attenuation of at least 100 is used.
Using OTR there is enough intensityto measure 4 upper decades;lower two decades need gain ofabout 100 to be measured.
The key elements: image intensifiers alignment and linearity combining algorithm(s) understanding CCD saturation
Intensity range that canbe measured without additional gain
Intensity range whereadditional gain of ~ 100is needed.(not high for an imageintensifier)
To be measured withimaging sensor #1and attenuation ~ 10
To be measured withimaging sensor #2and gain ~ 200
UBW2012, Berlin, December 2012
Raw images and combining algorithm
Two images (on the left) measured simultaneously with integration times 20 us and 400 us
Background measurements and subtraction is crucial!Made separately for two sensors and subtracted on-line.
Combining algorithm is efficient enough to provide 5 Hz rep. rate for 1024x768 images
At the time of measurements was limited by the flexibility of DLPC
Demonstrated dynamic range of ~ 5E+4 (factor of 100 increase)
Integration time is used for normalization and overlap (sufficient)
Averaging also improves SNR and therefore DR (beam stability)
Data combining algorithm
UBW2012, Berlin, December 2012
linear & log; the “trouble” with the RMS
The two images show exactly the same data (beam profile - (x,y))but in linear and log scale
Next step is to use such measurements for beam characterization, emittance and Twiss parameters measurements (add x’ and y’)
Ultimately tomographic measurements are planned; but first just quad scan
For non-Gaussian beam RMS beam width is a tricky thing!It depends on how much of tails of the distribution function f(x)is taken in to account.
UBW2012, Berlin, December 2012
Quadrupole scan raw data
Level of interest(LOI)
more tails included
less tails included
UBW2012, Berlin, December 2012
Emittance and Twiss parameters
beta function(s) alpha function(s)
RMS emittance
more tails included
less tails included
UBW2012, Berlin, December 2012
Diffraction limit and PSF
Imaging measured distribution is a convolution of source distribution and so-called Point Spread Function (PSF)
PFS determined by optical system angular acceptance but also by the source angular distribution. Different beam viewers have different PSF.
Diffraction determines rather hard limits to the DR
Ways to mitigate: increase angular acceptance, use spatial filter, coronagraph-like optics
UBW2012, Berlin, December 2012
Objective Lens Pupil Apodization
First a Lyot’s coronagraph was considered to improve the PSF, but this would not allow for simultaneous measurements of the beam core and halo, but it is a good exercise
Domain of Fourier optic, always Fresnel approximation – numerical calculations required for most of the interesting cases – becomes demanding on CPU and memory quickly due to large apertures and optical wavelength (~ 0.5 um)
Implemented and used quasi-discrete Hankel transform for optics modeling (allows to do 1D calculations vs. 2D)
Fourier optics mage plane = Fourier transform of pupil function for a point source (this is the PSF)
Then it is easy to see that the uniform pupil function, i.e., the harp lens edgeis the problem (besides the uncertainty principal, which also adds to the problem)
Apodization – modification of the pupil function; First considered Gaussian amplitude apodization
optical field propagation by means of qDHT
(false colors – intensity in log scale)
r
z
Uniform pupil function
Gaussian pupil with s=r0/3
UBW2012, Berlin, December 2012
Objective Lens Pupil Apodization
Point Spread Functions
Convolutions: PFS and 2D Gaussian
First a Lyot’s coronagraph was considered to improve the PSF, but this would not allow for simultaneous measurements of the beam core and halo, but it is a good exercise
Domain of Fourier optic, always Fresnel approximation – numerical calculations required for most of the interesting cases – becomes demanding on CPU and memory quickly due to large apertures and optical wavelength (~ 0.5 um)
Implemented and used quasi-discrete Hankel transform for optics modeling (allows to do 1D calculations vs. 2D)
Fourier optics mage plane = Fourier transform of pupil function for a point source (this is the PSF)
Then it is easy to see that the uniform pupil function, i.e., the harp lens edgeis the problem (besides the uncertainty principal, which also adds to the problem)
Apodization – modification of the pupil function; First considered Gaussian amplitude apodization
UBW2012, Berlin, December 2012
Wire scanner measurements
wire with diameter much smaller than the beam size interacts with beam as it is scanned across it
there is a number of interaction mechanisms:
beam capture secondary emission scattering
different ways to detect the signal
induced current secondary particles (counting)
Only 1D projections (no 2D distribution)
Takes time (“patience limited”)
LINAC beams are non-equilibrium(non Gaussian)
A. Freyberger, in DIPAC05 proceedings,Measurements made at CEBAF
at JLab FEL
UBW2012, Berlin, December 2012
Wire-scanner viewer combination
Designed to allow measurements of OTR photons, not Bremsstrahlung X-rays, gammas
low Z wires for OTR; still can use high Z wires if Bremsstrahlung is better
Viewer can be OTR or YAG, or other scintillator (normal to the beam)
Mirrors must be very good in terms of scratch and dig spec. – minimize scattering
Must have impedance shields (at JLab FEL)
Two diagnostics at one location
UBW2012, Berlin, December 2012
Wire-scanner electronics etc.
One key problem is the required measurements timeshould keep as short as possible to make the diagnostics practical
Maximum useful counting rate is the important parameter
The quest - counting system with the max rate of 100 MHz
PMTs themselves are fast enough for this
PMT base (HV divider) is tricky though, high rate high current loading of HV power supply changes HV changes gain (passive divider are not good for high rate)
There are a few different options for the PMT base, we plat to use so-called transistorized bases (high beta, high voltage transistors)
Preamplifiers, discriminators, logic etc. – commercially available
Need time resolution !!! Options are: gated counting, Time Correlated Single Photon Counting (TCSPC)
Counter, Multi-channel counters and TCSPC: FPGA implementation
UBW2012, Berlin, December 2012
LDR measurements state
we have demonstrated beam imaging with DR increased by ~ 100
applied the LDR imaging to beam characterization and have shown that for LINAC non-Gaussian beam the DR has strong impact on the measurements results
have modeled optics required to improve the DR range to reach 106
new diagnostic station for LDR imaging and cross-check with wire scanner was designed and built
next1 - practical implementation of the apodization optics (manufacturing, error sensitivity study, optimization)
next2 - beam measurements with new diagnostics (tomographic phase space measurements based on LDR imaging)
UBW2012, Berlin, December 2012
CEBAF: overview
Ebeam was 6 GeV is being upgrade to 12 GeV Bunch charge: 0.2 pCRepetition rate: 499 MHz (x3)Three independent beams (3 Halls)
1. Beam halo hitting beam pipe would create background in the NP detectors 2. FE in LINAC cavities affects the trip rate, which reduces up time and must be limited
UBW2012, Berlin, December 2012
CEBAF: trip rate, statistics
JLAB-TN-05-57 J. Benesch,Field Emission in CEBAF's Superconducting RF Cavities and Implications for Future Accelerators
JLAB-TN-10-008 J. Benesch,Comparison of arc models from March 2003/Nov 2004 and December 2009
JLAB-TN-12-049 J. Benesch, A. Freyberger,CEBAF Energy Reach and Gradient Maintenance Needs
Uses “accounting” and statistical analysis of the trip rate and its dependence on the cavities gradient
For 12 GeV CEBAF; 400 cavities + each cavity trips 1/(2 days) would result in on average 8 RF trips per hour
Original C25 design / unfortunate feature / RF window has a direct line of sight to the beam – charges up / eventually break down
With time performance of cavities degrades i.e. at the same gradient trip rate goes upexact mechanism is not known (speculated that # of FEs goes up)
Conclusion – gradient maintenance is needed (reprocessing cavities and refurbishing the cryo modules)
UBW2012, Berlin, December 2012
CEBAF: trip rate
Distribution of gradients in C25 cavities that resulted in 1/(2 days) trip par cavity
Initial distribution of gradients of C50 cavities
Distribution of gradients of the same C50 cavities at the end of 6 GeV operation (~ 4 years later)
Courtesy of J. Benesch
UBW2012, Berlin, December 2012
CEBAF: no Halo ?
One ways to make large dynamic range measurement is to arrange it to be frequency measurement
Then make it work for 1 Hz and for 100 MHz and this is 108 dynamic range. For instance use PMT and keep them working in counting mode
Courtesy of A. Freyberger
UBW2012, Berlin, December 2012
CEBAF: vacuum
Despite the idea/claim that CEBAF beam is quite Gaussian and has no or very little large amplitude non Gaussian tails,there are vacuum “events”
Two types of events:
1. Burn through that require a new piece of beam pipe to be fabricated as it has a hole drilled into it.2. Low current, very low intensity lose (chronic lose) that heats up a flange. This requires Rad. Con. to identify the hot spot, and then the flange is tighten up and the region recovers quickly.
Frequency of such events is 1-2 per year (35 weeks of operation)
Type2 is due to some kind of beam that is not seen (not looked for)
Type1 (some of them) related to rapid energy change due to RF changes
Fortunately it did not happen close to the SRF LINAC
UBW2012, Berlin, December 2012
Conclusion / Summary
JLab FEL (IR/UV Upgrade)
RF gradients in LINAC always require attention, set radiation background level (F.E.)
Drive Laser transport if made very carefully, seems to be not a problem
Drive Laser rep. rate control (EO cells) always need attention (extinction ration drifts)
Cathode suffers when conditioning and from breakdowns, still makes beam as needed, but scatters DL light – generates some halo
Non-linear beam dynamics is responsible for some fraction of the halo. When setting up for high current operation, a lot of effort and time goes in to “fitting” the halo through the recirculator, such that peak beam brightness does not suffer.
Radiation monitors, BLMs and vacuum are used as tuning diagnostics
CEBAF
NP detectors (background) require essentially no beam halo
Large statistics of cavity performance and its evolution (F.E.)
Direct effects of F.E. – RF trip rate, reduction of max. possible energy
Vacuum events related to beam loss (both high and very low current)
UBW2012, Berlin, December 2012
Backup slides
UBW2012, Berlin, December 2012
FEL Injector as an example of #1 (1/6)
downstream ofthe gun
UBW2012, Berlin, December 2012
FEL Injector as an example of #1 (2/6)
upstream of thebuncher cavity
UBW2012, Berlin, December 2012
FEL Injector as an example of #1 (3/6)
downstream of thebuncher cavity
UBW2012, Berlin, December 2012
FEL Injector as an example of #1 (4/6)
upstream of theSRF cavity 1
UBW2012, Berlin, December 2012
FEL Injector as an example of #1 (5/6)
downstream of theSRF cavity 1
UBW2012, Berlin, December 2012
FEL Injector as an example of #1 (6/6)
downstream of theSRF cavity 2
UBW2012, Berlin, December 2012
Beam Loss Monitors The primary BLM at the JLab is a 931B Hamamatsu photo-multiplier tube,
operated with a fixed integrator and individually variable HV power supply
The BLM electronics are 12 channel VME boards. PMTs are used in current (analog) mode There is a single FSD fiber output to the MPS for each VME board All 12 channels have analog monitors that are connected
to the Analog Monitoring System (AMS) These are used as tune-up diagnostics in the control room
Calibration procedure machine is locked into 1 uA CW operation beam is driven into chamber and detector gain is varied by changing HV the HV is adjusted until the system trips this new “gain” setting is saved in EPICS and accounts for aging of tube.
Ch3: Fault Trigger H = No Fault L = FSD Fault
CH1: Drive Laser Intensity
Courtesy of K. Jordan, D. Sexton