1. Photon Systems Breakout Lehman Review July 11, 2007
XTOD Diagnostics
Photon Systems Breakout
Lehman Review
July 11, 2007

2. FEE (Front-End-Enclosure)
LCLS Layout
FEE (Front-End-Enclosure)
Diagnostics
SOMS
HOMS
Linac
Undulator Hall
X-Ray Tunnel
FEH (Far Experimental Hall)
NEH (Near Experimental Hall)

3. XTOD Commissioning Diagnostics and Offset Mirrors in the Front End Enclosure (FEE)
Wall penetration
K Spectrometer
Indirect Imager
Slit
Solid
Attenuators
Collimators
Wall penetration
Thermal Sensor
Fixed
Mask
Gas Attenuator
Gas Detector
Beam Direction
Gas
Detector
Direct Imager
(Scintillator)
FEL Offset Mirror Systems

4. XTOD Optics and Diagnostics in FEE
5 mm diameter collimators
Gas Detector
Soft X-Ray Offset mirror system
Hard x-ray Monochrometer
(K Spectrometer)
Direct Imager
Solid
Attenuator
NFOV
Slit e-
Indirect Imager
Total
Energy
Thermal Detector
Hard X-Ray Offset mirror system
Gas
Attenuator
WFOV
Gas Detector
Start of Experimental
Hutches
Muon Shield

5. Attenuator on order N2 boil-off (surface) Flow restrictor
Gas detector
Flow restrictor
4.5 meter long, high pressure N2 section
Differential pumping sections separated by 3 mm apertures
3 mm diameter holes in B4C disks allow 880 mm (FWHM), 827 eV FEL to pass unobstructed
Solid attenuators
N2 Gas inlet
Green line carries exhaust to surface
Gas detector

6. Gas detectors share differential pumping with the Gas Attenuator
PMT
Electronics
Photo Multiplier Tube
Bandpass Filter
Al liner
3 mm apertures
along beam path
Differential Pumping
Section
Magnet Coils
Cylindrical Vessel
Beam / Gas Interaction Region
(~0.1 – 2 Torr N2)
Magnet Power Supply and Controller
APD
Gas Feed
And
Pressure Control
LCLS X rays cause N2 molecules to fluoresce in the near UV

7. Gas detector SSRL prototype
Port for pumping
Photo Multiplier Tube
Magnet Coils
Be window
Gas Feed
And
Pressure Control
Avalanche
Photodiode
Port for LED illuminator and florescence samples

8. Prototype Gas Detector insert for measuring x ray induced photoemission of candidate wall materials

9. Gas Detector signal vs. magnetic field at various pressures
Simulated
Measured

10. Results of SSRL Gas Experiments: Comparison Model and Experiments
(2X correction of calculated signal)
We suspect that discrepancy at lower pressures is due to photo electrons (and secondaries?) hitting the chamber ends

11. Measured luminescence of solids at 8 keVAl
UV signal closely represented by 9:00, B on (red): Al is the best

12. Time dependence of gas detector signal from the 8keV fundamental
UV signal within
X rays scattered into walls
~ 1 ns
X rays scattered into detector window ?
Photoelectrons hitting walls
0 – 18 ns
Photoelectrons hitting end caps
0 – 15 ns
Secondaries hitting walls and end caps
0 – 200 ns (?)
Energy of photoelectrons deposited into N2
0 – 45 ns

13. Indirect imager finds spontaneous core
Raw soft spontaneous
After reflection
Princeton Instruments back illuminated CCD camera
25 x 25 mm chip, 20 um pixel size
ML mirror 0.1% reflectivity,
1% bandwidth
Status Indirect Imager:
PRD in progress
Vacuum chamber

14. Detector monochrometer measures intensity at a single point
Channel-cut Si Monochrometer will be used to measure relative K of two undulator segments
Monochrometer
Two undulator spontaneous spectrum. Falloff of high energy tail is independent of aperture
Detector
Detector monochrometer measures intensity at a single point
Linac E variation and
measurement
Use linac E variation and measurement to obtain other points along curve
Two undulator spontaneous high energy falloff has highest slope when DK/K=0.
Status K Spectrometer:
PRD in progress

15. Total Energy (Thermal) Sensor provides calibrated measurement of FEL pulse energy
Measures FEL energy deposition through temperature rise
Cu heat sink
Thermistors
Nd0.66Sr0.33MnO3
(On back of substrate)
Sensor Temperature Rise 1 2 3 4 5
0.05
0.1
0.15
0.2
0.25
0.3
Time [ms]
Tc200
Tc150
Tc100
FEL pulse
[K]
0.5 mm Si substrate
t = 0
t = 0.1 ms
t = 0.25 ms
Thermal diffusion of FEL energy
Status Thermal Sensor:
PRD done
SCR done
PDR done
Prototype done
FDR in progress

16. Thermal sensor prototype
Pulse tube cooler
Optics for measuring, focusing, and steering laser beam
532 nm laser
Sensor cryostat

17. Thermal sensor signal at 1mJ
2 volt bias
0 volt bias V1 V1
Vbias
Rsensor R1 V1 V2 R3 R4 V2 V2

18. Channel 1 pulse at 400 uJ with 2V bias
Subtract value at -100us
Sample voltages at particular times, convert to DRcmr then to DT

19. Total energy prototype measured and predicted signal
Finite difference prediction
DT, °K
DT, °K
Measured data
Absorbed Laser Energy, mJ
Absorbed Laser Energy, mJ
At 100 msec
At 3 msec

20. Thermal sensor, preliminary design
Thermal Detector
Calibration Laser
Laser Energy Meter

21. Scintillators on movable shaft Photodiode for K measurement
Direct Imager
30 fps CCD Camera
Scintillators on movable shaft
ND filter wheel
High resolution lens
4 Scintillators:
Thin, stops 8 keV FEL
find soft x-ray FEL
Very thin, stops 826 eV FEL
Thick, stops spontaneous
spontaneous studies
+ one other for tests
diamond
Stops FEL
Transmits spontaneous
Photodiode for K measurement
30 fps CCD Camera
Low resolution lens

22. Direct Imager, preliminary design
Single shot measurement of f(x,y), x, y ,u
Camera
Status Direct Imager:
PRD done
SCR done
Prototype done
PDR done
in Final Design
Scintillators

23. Scintillator emission spectrum
Camera QE
Scintillator emission spectrum

24. Soft X-Ray Spontaneous signal in WFOV Direct Imager
Absorbed in 5 um YAG,
Maximum ~ 20,000 photoelectrons/pixel
Camera: Photometrics 512B
Objective: Navitar Platinum 50
Power:
NA:

25. Scintillator signals in FEL equivalents
Needed x-ray attenuation
Needed x-ray attenuation
YAG Range
Needed visible attenuation
CCD Range
Need x-ray attenuation of > 100 and visible attenuation of > 10

26. Prototype Direct Imager testing
Flat field testing of camera only
Enclosure
CCD
Integrating
Sphere
Camera
Pulsed UV laser testing with YAG
WFOV Optic
UV beam splitter
N2 Laser
YAG
Insertable photodiode
Lens
ND filter
Photodiode

27. Photon Transfer Curve
Our fit:
Manufacturer:

28. Cascade 512B on-chip gain measurements
On-Chip: 0 to 4000,
Exposure Time: 5 to 190
Lamps: 1, 2
Measured Gain = Slope g(j)/Slope g(0)
On-Chip
Gain
Measured
Gain
Slope
45.09
500
62.44
1000
77.59
1500
106.06
2000
168.20
2500
307.83
3000
848.24
3500
1.00
1.38
1.72
2.35
3.73
6.83
18.81
60.39
February 12, 2007 Run 12

29. Direct Imager image of N2 laser excited YAG scintillator at 20 Hz
YAG excited by N2 laser
Boundary of 10 mm dia. YAG disk

30. FEL Offset Mirror Systems have “Pop-in” imagers for alignment

31. Bidirectional Popup Viewer allows viewing of the x-ray beam and the collimator

32. We are studying expected signal levels in the Pop-in cameras
Low Energy, All undulator modules
100% Spontaneous
Propagated through fixed mask, pipes
12 Boron Carbide windows are open
Slit is open
No attenuation, no gas detector
Photons absorbed in 1 mm YAG,
Full Well: 200,000
# photoelectrons ~ 5660 per pixel
Misses Mirror 1
Reflected
off Mirror 1
SOMS Run005

33. Progress continues on XTOD diagnostics:
Summary
Progress continues on XTOD diagnostics:
Procurement - Slit, Fixed Mask, Attenuator
PDR – Direct Imager, SOMS, Thermal Detector
SCR – K-Spectrometer
PRD – HOMS, Indirect Imager