1. The LCLS Injector C. Limborg-Deprey Injector-Linac & Spectrometers Nov 20th, 2006

2. Beam Characterization
Introduction
Beamline Layout
Emittance compensation
Beam Characterization
6 MeV
135 MeV
On-line Computation Tools
Single-particle
Multi-particle

3. LCLS
SASE occurs along undulator from a very dense high energy electron bunch with small divergence and small energy spread
Driver
1- “Injector” high brightness beam
2- “Linac” compression, acceleration (+ preservation of emittance )
P = P0
eN = 1.2 mm
eN = 2.0 mm
P = P0/100
P  exp(z/Lg) with Lg  (/I)1/3
 < at 15 GeV ( ~ 1.5Å)
n ~ 1.2 m , I ~ 3.2 kA
courtesy S. Reiche

4. LCLS Injector High Brightness beam driver
to generate high charge density in the 6D phase space
Technology
RF Photoinjector +
“Emittance compensation”
Challenges
Laser performance, stability
ELM fields quality
Optimization

5. LCLS Injector Klystron Gallery Laser Room focusing solenoid
cathode flange
dual rf power feed
focusing solenoid
Klystron Gallery
Laser Room
BC1 compressor
DogLeg
Gun
2 linacs

6. injector spectrometer
LCLS Injector Design Parameters
RF Gun
6 MeV
n~1.6 mm-mrad
E, uncorr ~ 3 keV
Design
n,slice ~1.0 mm-mrad
100 A (1nC, 10 ps)
62 MeV
n ~1.0 mm-mrad
E, uncorr ~ 3keV
gun spectrometer
135 MeV
n ~1.0 mm-mrad
E, uncorr ~ 40keV
“Laser heater “
(2008)
L1 RF section
(21-1b)
main SLAC Linac
injector spectrometer
sector 20
sector 21

7. LCLS Injector Diagnostics
YAG screen
RF Gun
trajectory (BPMs)
emittance (+ slice)
energy spread (+ slice)
bunch length (+ dist.)
charge (+ dark current)
YAG screen
YAG screen
YAG
screen
(YAG screen)
gun spectrometer
Transverse RF deflector
OTR & wire
OTR & wire
OTR & wire
OTR & wire
main SLAC Linac
injector spectrometer
YAG
YAG & OTR

8. 0.5 nC requires only QE of 10-5 with laser energy of 250 J
RF Photo-Injector
1- Laser system
Pulse (~ cylindrical shape + uniform)
Energy 255nm)
2- Photocathode
Quantum Efficiency (QE)
Uniformity of emission
3- High gradient RF gun
0.5 nC requires only QE of 10-5 with laser energy of 250 J
LCLS Min QE
Courtesy S.Gilevich
Courtesy E.Jongewaard
Courtesy D.Dowell

9. Emittance 1- Slice/projected 2- At emission : cathode emittancex
1- Slice/projected
2- At emission : cathode emittance
x’ = dx/dz z x
 = 2.34 mm.mrad
 = 1.16 mm.mrad
 = 0.75 mm.mrad
Distribution of transverse momentum
Px,Py of photo-electrons
extracted from cathode

10. (while being accelerated)
Emittance compensation
Solenoid
Linac
Gun m X’ e m e
Space charge force
Smaller at end of bunch (e) than at middle (m) x X’
Solenoid
Focusing lens z e x
Drift
(while being accelerated)
Drift +
Space charge X’ X’ x X’ x X’ m x x m e
Slices realigned at best
Distribution frozen at high energy e

12. Emittance compensation
Key parameters
Gun (Vrf, rf )
Solenoid field values
Laser beam (volume, uniformity)
Emission (QE uniformity)
Alignment, Steering
rf = 2 
Solenoid 0.3%

13. Commissioning baseline parameters
Limits
Q ≤ 500pC
repetition rate ≤ 30Hz
Gun gradient ≤ 120 MV/m
Satisfactory results for 2007 would be
 < 1 mm-mrad for Q > 200 pC
(much more forgiving on laser characteristics)
Optimization
For given charge, vary
Laser radius, rf, Vrf, Bsolenoid 1,Bsolenoid 2, VL0a
Steering (laser pointing, steering in L0a)

14. 6 MeV transverse measurements
YAG02
YAG01
FC01
Courtesy J.Schmerge
Solenoid
Emission characterization QE
Charge vs laser energy (for different rf)
(total QE & QE vs x,y position laser on cathode)
Cathode Uniformity
Cathode emittance measurement
( also Px,Py distribution)

15. Imaging cathode Point-to-point imaging of cathode Virtual cathode
Direct determination
Uniformity of emission
Ellipticity
Transv. rise/fall slopes
e image : hot spot
electrons image
Tuning depends
E gun
Solenoid calibration
(best with short laser pulse)
Getting initial conditions. Use complementary laser image for init distribution. Find image point of ebeam. Measure emitted distribution. Use in simulations.
Courtesy W.Graves
Cathode Image at DUVFEL

16. Cathode emittance Cathode emittance Direct determination
cathode (with appropriate set of Vrf, rf, Bsolenoid)
Momentum distribution
 initial model + cathode quality
Infinite-to-point imaging
of cathode
Assumes cathode = 0.6 mm.mrad
Image of divergence of source
At YAG02 , with Vrf reduced

17. Imaging source divergence
Momentum at cathode
Imaging source divergence
Best parameters
Vrf, ~ 72 MV/m
rf ~ 20 degrees
Observation at YAG02

18. 6 MeV Longitudinal measurements
Spectrometer
85  Bend
YAG01
p(GeV) = 0.3 B(T)(m)
YAGG1
Energy
Absolute energy
Calibration Vrf vs Prf (MW)
Correlated Energy Spread
Optimal rf
Slice thermal emittance
Relay imaging system from YAG01 to YAGG1
Uniformity of line density

19. Horizontal Projection Linear Scaling of Energy atYAG01
High Charge operation
6 MeV Longitudinal measurements
Temporal pulse , … using quadrupoles to project manageable size on screen
Head
Horizontal Projection
Linear Scaling of Energy atYAG01
8% modulation
on laser pulse
at YAG01
at YAGG1

20. 135 MeV Transverse Measurements
See P.Emma Presentation
3 screen emittance
(OTRs, WS)
Horizontal Slice emittance
(TCAV, Quad Scan)

21. 135 MeV Longitudinal measurements
Energy
Correlated Energy Spread
Uncorrelated Energy Spread
Bunch Length
Direct Longitudinal Phase Space
Slice vertical emittance
DL1
135 MeV
Spectrometer
135 MeV Spectrometer
35 degrees Bend

22. Longitudinal Phase Space at TCAV
135 MeV Longitudinal measurements
Direct Longitudinal Phase Space measurement
Transverse deflecting cavity  y / time correlation
(with V = 1MV, 0.5mrad over 10ps )
Spectrometer  x / energy correlation
Resolution requirements : 7 m for nominal optics
(OTRS1 has 11m resolution ok for modified optics)
DL1
Longitudinal Phase Space at TCAV
135 MeV
Spectrometer
Spectrometer Screen

23. resolution 6 keV for nominal optics
resolution 3 keV for modified optics
3keV -> 40 keV will be measurable
rms
Direct Measurement
Projection

24. Risk: Solenoid Alignment
Tools
Single Particle Tracker in Matlab for on-line modeling
gun to L0a (including misalignment of components + earth magnetic field)
to be extended to DL1 (i.e linacs + quads) & spectrometers
Support tool for :
Steering (SC0 in Solenoid 1)
Alignment
Search for imaging parameters (cathode, divergence, dark current … )
Energy calibration (Vrf, rf )
All low charge measurements
Solenoid
SC0
SC1
SC2
Gun
BPM2
BPM3
L0a
BPM5

25. Risk: Solenoid Alignment
Single Particle Tracker : steering in L0a
After steering
<0.1mm,<0.12mrad
Using SC0, SC1
Solenoid misaligned
Bearth
Without steering
4mm, 4mrad
Solenoid
Solenoid
SC0
SC1
SC2
Gun
BPM2
BPM3
L0a
BPM5

26. Single Particle tracker
Dark current studies for gun
Solenoid
Gun
YAG01

27. Tools : Multi-particle tracking
Start-to-end simulations
Using Linux cluster (64 to 128 processors)
Methodology
Input Laser distribution
Use model
Track through injector
Compare simulations/data
Feed other codes ( ELEGANT, GENESIS/) for downstream transport
Correct model (from calibration with beam)
Code choices for Injector
PARMELA , IMPACT , ASTRA
Useful in control room only if runs do not exceed 15 minutes from cathode to DL1 for 3D with 200k particles
Example of simulation: emittance compensation with PARMELA

28. Parameter Scan : Beta matching
Scan parameters : (rf, Vrf , B solenoid)
Large Variation of betatron function while varying Bsolenoid
Rematching necessary for emittance measurements
3 screen emittance : best resolution for perfect parabola
(with 60 degrees phase advance between screens)

29. Tuned to matching of -0.6% case Matching performed for each point

30. Commissioning Strategy
1st Pass : beam to 135 MeV
Start-up equipment to reach 135 MeV
Software checkout
2nd Pass : first order optics
steering
matching
3rd Pass :
Characterization:
Transverse emittance (slice & projected)
Longitudinal phase space (slice energy spread)
Optimization :
Fine tuning of gun
Scan of parameters ( scans of solenoid fields, phase, voltage …)

31. BACK-UP

32. LCLS Injector Magnets Gun Solenoid RF Gun L0a Solenoid QA01,QA02 BXG
QE01,QE02
QG01,QG02
QE03,QE04
QM01,QM02
BX01
BX02 QB
main SLAC Linac
BXS
QS01,QS02

33. Emittance compensation
Phase space evolution x X’
Drift x X’ x X’
Focusing kick
(ex Solenoid
RF entrance cell)
Defocusing kick
(ex: RF kick at exit gun , space charge ) x X’ x X’
Solenoid kicks are energy dependent
Space charge kicks are density dependent
Space charge (defocusing) in drift on a converging beam
Space charge (defocusing) in drift on a diverging beam

34. 100MV/m, 2 Gaussians, 0.5 nC < {10,90} > ~ 0.7 mm-mrad
Parameters improved by using
a 0.6 mm radius beam
80 ~ 0.78 mm-mrad
< {10,90} > ~ 0.6 mm-mrad

35. Risk: Solenoid Alignment
Tolerance : 250 m, 250rad w.r.t to gun electrical axis
Requires beam based alignment
Method :
1) Determine center of cathode
2) Determine error in position of solenoid with few steps of solenoid motion
F(X, rf, Vrf, Bsol, Xsol) = Xf
4 unknowns Xsol = (x,x’,y,y’)
Center BPM/Screen cannot be determined with beam
Angle resolution from BPM2-BPM3 > 100 rad
Code
Single Particle tracking in Matlab for on-line modeling ( similar to V-code)
gun to L0a (including misalignment of components + earth magnetic field)
to be extended to DL1 (i.e linacs + quads)
Solenoid
SC0
SC1
SC2
Gun
BPM2
BPM3
L0a
BPM5

36. Risk: Solenoid Alignment
1) Center of cathode
Steer laser centroid on 2D grid
Scan Gun RF phase
Gun
YAG02
Centroid on cathode
Centroid on YAG01, rf [24,36]

37. Risk: Solenoid Alignment
2) Mispositioning Solenoid
(Position, Angle ) does not vary with strength when the Solenoid aligned Vary Solenoid strength
Assume center cathode known to better than 50 m
Assume axis gun on screen is known within 50 m
Requires at least 8 motions of solenoid

38. Risk : Laser Pulse shape
Difficult to meet specifications
Rise time 1 ps
Uniformity 10% ptp
Pulse stacker
with 2-3 gaussians give satisfactory performances
Even better for compression (flatter at 135 MeV )
NEED to ADD standard pulse
(n) gaussians p
80
<10,90>
(2) TP_G02
1.41
1.23
0.97
(3) TP_G03
1.24
1.11
0.91
“Square”
1.08
0.8

39. Risk : Gun field
if 120MV/m difficult (breakdowns and large dark current)
110 MV/m gives performances very similar to 120 MV/m
100 MV/m is also gives acceptable performances (see next slide)
( for 0.5 nC, 80 < 0.8 mm-mrad )
Q [nC]
Laser pulse
Gun Field
80 mm-mrad
proj.mm-mrad
z [mm]
0.2
6.5 ps
120 MV/m
0.35
0.44
0.657
110 MV/m
0.37
0.704 1 10
0.91
1.08
0.948
0.95
1.05
0.97 12
0.92
1.02 14
0.88
1.157

40. 100MV/m, 2 Gaussians, 0.5 nC < {10,90} > ~ 0.7 mm-mrad
Parameters improved by using
a 0.6 mm radius beam
80 ~ 0.78 mm-mrad
< {10,90} > ~ 0.6 mm-mrad

41. (while being accelerated)
Emittance compensation x X’ e m e
Space charge force :
Smaller at end of bunch (e) than at middle (m) z m X’
Drift +
Self-defocusing X’
Focusing lens x X’ e x x m m e e X’ x X’ x X’
Drift +
Self-defocusing
Drift
(while being accelerated) m x e
Slices realigned at best
Dis. frozen at high energy

42. Emittance compensation
Gun
Solenoid
Linac
Diverging: Space charge
RF kick at exit cell
Converging: Solenoid
RF kick at entrance cell

43. Self-field from Relativistic Electron BeamsEr
Er = 6MV/m for a 1nC in cylinder of (r=1 mm, L =3 mm) Er r Ez
 r
 1/r2
 ‘

44. Emittance compensation
Gun
Solenoid
Linac

45. Emittance 1- Emittance 2- Emittance at emission z  = 2.34 mm.mrad

46. LCLS Injector RF Gun L0a RF section L0b RF section gun spectrometer
6 MeV
L0b RF section
62 MeV
gun spectrometer
Transverse RF deflector
135 MeV
L1 RF section
(21-1b)
main SLAC Linac
injector spectrometer
sector 20
sector 21

47. High charge and small emittance
Photoinjector
High charge and small emittance
Compressors
Small bunch length
Preserving emittance
135 MeV
250 MeV
4.5 GeV
15 GeV
10 ps
2.3 ps
230 fs
n,slice ~ 1.2 mm.mrad
Ipk = 3.4 kA (230fs, 1nC)
 < , 14.3 GeV

48. LCLS Injector Gun S1 S2 L0-1 L0-2 ‘Laser Heater’
19.8MV/m
L0-2
24 MV/m
‘Laser Heater’
‘RF Deflecting cavity’ TCAV1
3 screen emittance measurement
6 MeV
 = 1.6 m
,un. = 3keV
63 MeV
 = 1.08 m
135 MeV
 = 1.07 m
DL1
,un. = 40keV
Spectrometer
Linac tunnel
UV Laser 200 J,  = 255 nm, 10ps, r = 1.2 mm

50. Gun Characterization QE, thermal, Uniformity Emission , Bunch Length
YAG1
YAG2
CR1
YAGG1
CRG1

51. Courtesy J.Schmerge, GTF
QE from Schottky Scan
Direct determination of QE
RF for a given Vrf
Courtesy J.Schmerge, GTF

52. More Profile measurement
Standard “Beer Can”
“3D-Ellipsoid”

53. Cathode Imaging Point-to-point imaging of cathode
Cathode Image at DUVFEL
Virtual cathode
Virtual cathode
Direct determination
Uniformity of emission
Ellipticity
Transv. rise/fall slopes
e image : hot spot
electrons image
Result Correlated to
E gun
Solenoid calibration
(from mask image rotation )
Getting initial conditions. Use complementary laser image for init distribution. Find image point of ebeam. Measure emitted distribution. Use in simulations.
Courtesy W.Graves

54. Cathode emittance Direct determination
cathode (with appropriate set of Vrf, rf, Bsolenoid)
Momentum distribution
 Fundamental for initial model + cathode quality
Correlated quantities
E gun
Solenoid calibration
Assumes cathode = 0.6 mm.mrad
Image of divergence of source
At YAG2 , with Vrf reduced

55. Imaging source divergence what type of momentum distribution?
Momentum at cathode
Imaging source divergence what type of momentum distribution?

56. More Profile measurement
Standard “Beer Can”
“3D-Ellipsoid”

57. Solenoid = 98 A Data Parmela Solenoid = 104 A Solenoid = 108 A
DUVFEL EXPERIMENT
Good match of Slice Emittance and Twiss Parameters
Parameters: 200 pC
Solenoid = 104 A
Solenoid = 108 A

58. Difficulties of Calibrations
 beam at YAG1 varies with Vrf , rf , Gun field balance, charge, Solenoid calibration
calibrate Vrf , rf (see slide 18-20)
then can possibly detect field unbalanced
Fit of DUVFEL measurements

59. Diagnostics Current Monitors Straight Ahead Spectrometer Wire scanners
Cerenkov Radiator
OTRs
YAGs
Gun
Spectrometer
EO monitor

60. Including Magnets
Treaty Point

61. 1 2 3 4 Linac tunnel ‘Laser Heater’ Straight Ahead Spectrometer
3 screen emittance measurement
‘RF Deflecting cavity’ TCAV1
Emission
thermal
Uniformity QE 2 3 4
Gun Spectrometer

62. 3 screen emittance measurement ‘RF Deflecting cavity’ TCAV1
6 MeV
 = 1.6 m
,un. = 3keV
63 MeV
 = 1.08 m
,un. = 3keV
135 MeV
 = 1.07 m
,un. = 3keV
135 MeV
 = 1.07 m
,un. = 40keV
Linac tunnel
‘Laser Heater’
Gun S1 S2
L0-1
19.8MV/m
L0-2
24 MV/m
DL1
Spectrometer
3 screen emittance measurement
‘RF Deflecting cavity’ TCAV1
Spectrometer
UV Laser 200 J,  = 255 nm, 5-20 ps, r = mm

63. Diagnostics Current Monitors EO monitor Cerenkov Radiator YAGs OTRs
Faraday Cup
EO monitor
Cerenkov Radiator
YAGs
OTRs
Wire scanners
Gun
Spectrometer
Straight Ahead Spectrometer

64. Injector Layout RF Gun L0a RF section L0b RF section gun spectrometer
6 MeV
L0b RF section
62 MeV
135 MeV
gun spectrometer
Transverse RF deflector
injector spectrometer
main SLAC Linac
sector 20
sector 21

65. Risk: Solenoid Alignment
2) Error of solenoid position
F(Xlaser, rf, Vrf, Bsol, Xsol) = Xf
Large systematic errors on Xf (reference 0 cannot be determined)
F(Xlaser, rf, Vrf, Bsol, Xsol) = Xf - Xf0
Determining Xsol is a very non-linear problem
Xsol = (xsol, xp,sol, ysol, yp,sol)
Xf reference (Xf0, Xfp0, Yf0,Yfp0)
 8 unknowns instead of 4

66. Risk: Solenoid Alignment
2) Error of solenoid position
Single Particle tracking in Matlab for on-line modeling ( similar to V-code)
gun to L0a (including misalignment of components + earth magnetic field)
to be extended to DL1 (i.e linacs + quads)
Algorithm to determine, in minimum steps, mis-positioning of the solenoid
F(X, rf, Vrf, Bsol, Xsol) = Xf
Issue :
4 unknowns Xsol = (x,x’,y,y’)
Center BPM/Screen cannot be determined with beam
BPMs too close together for good accuracy on angle
Angle resolution from BPM2-BPM3 > 100 rad
But Indirect evaluation of angle using BPM5
Only solution: model based analysis for complicated non-linear problem
Solenoid
SC0
SC1
SC2
Gun
BPM2
BPM3
L0a
BPM5

67. 100MV/m, 2 Gaussians, 0.5 nC < {10,90} > ~ 0.6 mm-mrad
With 0.6 mm radius beam
80 ~ 0.78 mm-mrad
< {10,90} > ~ 0.6 mm-mrad
Large margin for emittance increase from errors

68. LCLS Injector High Brightness beam driver
to generate high charge density in the 6D phase space
Technology
RF Photoinjector +
“Emittance compensation”
Challenges
Laser performance, stability
ELM fields quality
Optimization