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Summary from TTF2 Working Group

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Title: Summary from TTF2 Working Group

1
Summary from TTF2 Working Group Jean-Paul
Carneiro, Markus Koerfer DESY, Hamburg TESLA
COLLABORATION MEETING ORSAY, 7-Sept-2004
2
TESLA COLLABORATION MEETING WORKING GROUP
TTF2 LAL ORSAY, 7-SEPT-04 Morning (9H00? 10H30,
11H00?12H30) 9H00 ? 10H30 Carneiro
Cryogenics Installations TTF2 in 2004 and Future
Plans Lange (20) TESLA Cavities in
the VUV-FEL LINAC Modules Kostin
(20) Status of the TTF-II vacuum system
Zapfe (20) Power Supplies for TTF2 and
Pulse Cable for Modulator Eckoldt
(30) 11H00 ? 12H30 Koerfer Status RF
System Choroba (15)
Commissioning of the LLRF for the VUV-FEL
Simrock (10) RF Control Improvement for
TTF II with low latency FPGA feedback Jezynski
10 VUV-FEL Controls Rehlich
(15) TTF 2 Diagnostics Status and
Availability of Toroids, BPMs, Castro (15)
3
Afternoon (14H00? 16H00, 16H30?18H00) 14H00?
16H00 Carneiro TTF-VUV FEL Optical Systems
Castellano (15) Photoinjector Laser
Operation and Cathode Performance
Sertore (20) Beam based alignment, Dark
current and Thermal emittance Miltchev
(20) Status of Emittance Measurements at the
TTF/VUV-FEL Injector Honkavaara (20) First
Measurements on HOM-Based Alignment in the TESLA
Cavities Baboi (20) 16H30? 18H00 Koerfer
Improvements in LLRF control algorithms and
automatio Brandt (20)
TTF2-Time-Of-Flight Measurements
Kollewe (20) TTF2 Start-Up Simulations
Yurkov (20) TTF2 commissioning
strategy Castro
(10) Discussion about commissioning
Prepared but not presented (available on the
web) Attempt of measurement of linear
dispersion Golubeva (10) Commissioning
445-MeV Optics of the TESLA Test Facility Linac
Balandin (10) Velocity bunching simulations
for TTF2 Carneiro (10)
4
Cryogenics Installations TTF2 in 2004 and
Future Plans

-Assembly and installation of Module M2 (old
type II)
for Position ACC1
-Commissioning of the new TTF2 set up with
5 Cold Accelerating Modules
-Cool down, operation and tests of the new TTF2
set up
-Shut down June-04 until September-04
-Cryogenic operation possibillities/redundancies
Future
-Preparation and assembly Module M6 (new type 3)
-Fermilab buildts 3rd Harmonic Module (3.9GHz)
-Cryogenic supply for Superconducting Magnetic
Energy Storage SMES
-Module Teststand
-Update Cold Box Hall 3 (2 new screw compressors
already in operation)

R. Lange
5
TTF2 since March 2004
Automated Cryo-operation for TTF2-Linac
Linac Transfer
From/to CB HERA or CB Hall 3
Fermilab Feedbox
BCBTL2
BCBTL1
ACC2 Transferl
ACC1 Transferl
VB
VB
Endcap
ACC5 M5
ACC4 M4
ACC1 M2
ACC2 M1
ACC3 M3
BC2
BC3
Overview 21-Mar-04 Start cool down 28-Mar-04
4.3K/1.1bar 29-Mar-04 2 K / 31mbar 07-Jun-04
Shut down, but modules
stay cold at 4.3K/1.1bar 01-Sep-04 End of shut
down
GUN
Cryo losses static Watt Total Module 40/80K 1
300 74 4.3K 3201.6g/s 13 2.0K
21 lt3.5
R. Lange
6
TESLA Cavities in the VUV-FEL LINAC Modules
D. Kostin
7
Modules Operating Gradients
ACC3
ACC4
ACC5
ACC2
ACC1
D. Kostin
8
Cavities _at_ ACC1
EP cavity
D. Kostin
9
EP Cavities
(AC72 is installed in ACC1)
D. Kostin
10
S. Choroba
11
S. Choroba
12
S. Choroba
13
S. Choroba
14
S. Choroba
15
S. Simrock
16
S. Simrock
17
K. Zapfe
18
K. Zapfe
19
K. Zapfe
20
K. Zapfe
21
K. Rehlich
22
K. Rehlich
23
K. Rehlich
24
TTF 2 Diagnostics Status andAvailability of
Toroids, BPMs,
Prepared by D. Nölle
P. Castro
25
STATUS

Installation of diagnostics is completed
exception BPM electronics
BPM electronics available by end of 2004 (first
boards maybe in November).
For the commissioning use 20-15 TTF1 electronics
(DESY Frascati units)
Not useful for undulator (lt- Electronics
container inside the tunnel)
Problem Orbit tuning is not possible to required
precision
in the collimator
in the undulator

P. Castro
26
TTF/VUV-FEL Photon DiagnosticsStatus and
Availability
Prepared by R. Treusch
P. Castro
27
Availability of VUV FEL diagnostics
Parameter Detector(s) Online available
Intensity Profile thermopiles, PtSi photodiodes, MCPs no no limited now
Intensity Position Gas Ionisation Detector YES April 2005
Spectrum Grazing incidence spectrometer (tunnel) no now (Commissioning)
Spectrum VLS Grating Spectrom. YES mid/end 2006
Timing Streak camera YES April 2005
Timing Auto-/Cross-Correlators YES ? (experimental stage)
P. Castro
28
TTF-VUV FEL Optical Systems
LNF Frascati L. Cacciotti M. Castellano G.
Di Pirro O. Giacinti R. Sorchetti
Roma 2 L.Catani E. Chiadroni A.Cianchi M.
Raparelli
DESY K. Honkavaara
M. Castellano
29
Total Camera Number
18 Standard Optical System 3 Gun Camera 4 Fixed
magnification (1 BC2 3 Bypass) 2 Diffractors
All of them are working
M. Castellano
30
M. Castellano
31
K. Honkavaara
32
K. Honkavaara
33
K. Honkavaara
34
K. Honkavaara
35
D. Sertore
36
D. Sertore
37
D. Sertore
38
Beam based alignment, Dark current and Thermal
emittance measurements J-H.Han,M.Krasilnikov,V.Mi
ltchev, PITZ, DESY, Zeuthen

Beam based alignment
Laser alignment
Solenoid alignment
Dark current
Thermal emittance

V. Miltchev
39
Beam Based Alignment Conclusions

Beam based alignment (BBA) of the gun can be
done in two consequent steps
1. Alignment of the laser on the cathode
2. Solenoid alignment
Beam based laser alignment at PITZ is a
well-established procedure. To implement it at
TTF a calibrated camera at double diagnostic
cross screen is required
Mechanical beam line misalignment complicates
the BBA, introducing an additional uncertainty
Some steps in the gun solenoid alignment have
been done. It is complicated by an uncertainty
introduced by mechanical beamline misalignment,
not perfectly aligned laser on the cathode and
some uncertainty in machine parameters (rf field
amplitude and absolute phase, solenoid
calibration). For further alignment more detailed
study is needed.

V. Miltchev
40
Modeling of the Field Emission Source
Well conditioned (less dark current)
Edge of the Mo plug 8000 macro particles
Edge of Cs2Te film 2000 macro particles
Cs2Te flim (5 mm ?) 2000 macro particles
Mo plug (16 mm ?) 8000 macro particles
V. Miltchev
41
FC1 and FC2 (42 MV/m)
Faraday cup 1
Faraday cup 2
Main reason of the mismatch between measurement
and simulation beamline misalignment and the
effect of steerers. ? lower energy part of the
dark current is filtered out.
V. Miltchev
42
Thermal emittance measurements

The final goal is to estimate the average kinetic
energy Ek of the emitted photo electrons.
Assuming isotropic emission
An estimate for could be given by
measuring the transverse
emittance vs. laser spot r.m.s. size s,
provided that eRF, eSC 0
Use very small charge (2-3 pC) and short laser
pulses (6-8 ps FWHM)
Use single slit scanning and/or solenoid scan to
measure emittance
Check the dependence of the transverse emittance
on applied electric field on the cathode

V. Miltchev
43
Thermal emittance measurements
Transverse emittance for different r.m.s. laser
spot sizes measured with the single slit scanning
method at a charge of about 3pC and an
accelerating gradient at the cathode of 32 MV/m.
V. Miltchev
44
Thermal emittance measurements
Summary

The transverse emittance was measured for very
low charge of 2-3 pC and short laser pulses of
6-8 ps FWHM
The scaling of transverse emittance with laser
spot r.m.s. size was measured
The average kinetic energy Ek of the emitted
photo electrons was estimated to be 0.8 0.1eV
Thermal emittance was measured as a function of
the applied field a the cathode
An increasing of the thermal emittance with
accelerating gradient was observed

V. Miltchev
45
N. Baboi
46
N. Baboi
47
N. Baboi
48
M. Kollewe
49
M. Kollewe
50
M. Kollewe
51
M. Kollewe
52
M. Kollewe
53
M. Yurkov
54
M. Yurkov
55
M. Yurkov
56
M. Yurkov
57
TTF2 commissioning strategy
P. Castro
P. Castro
58
BEAM COMMISSIONING STEPS - SUMMARY