Title: Injector Drive Laser Update
1Injector Drive Laser Update
- Facilities Advisory Committee Meeting
- October 27, 2005
- Project Status
- Drive Laser
- Change in the Gun design
- Launch System Design
- Transport tubes Installation
- Response to the April FAC recommendations
- Summary
2Project Status
- The contract for the Drive Laser was awarded to
Thales Lasers. - Design review was held October 18 - 20
- Construction of the S20 drive laser facility is
underway. - Old building has been demolished
- Requirements to the electrical and water systems
were defined based on the Thales laser system
requirements - Design of the electrical system is near
completion. - Beneficial occupancy is planned for February 2006
- The Laser safety system design is underway.
- The laser safety review planned at the end of
November
3Project Status
- The laser beam transport tubes were installed.
- Tubes passed the leak check
- Design of the optical tables completed.
Procurement process started - Design of the active beam steering stabilization
system started. - The system will be tested in Build. 407
- Parts for the test were defined and ordered
- Optical Design of the Launch System for normal
incidence completed - The draft of the Drive laser Commissioning
schedule is put together - Schedule is being synchronized with the
commissioning schedule for the gun
4Project Status
- RD effort is underway.
- LLNL completed modeling of the UV temporal pulse
shaping. The UV conversion modeling code was
completed and run on a number of cases. It was
shown that to obtain efficient, temporally
uniform UV pulses that we need to convert the IR
beam to a spatial flat-top before frequency
conversion. - The temporal diagnostics designs were finished.
For UV and blue measurements TG FROG was
proposed. Orders were placed. - ANL performed spatial shaping of broadband IR
pulses using the Newport aspheric beam shaper.
Optimum shaping conditions were defined. It was
shown that extent of the bandwidth significantly
affects the quality of shaping - Work to arrange the collaboration with INFN and
Elettra started
5Thales Drive Laser System
150ps 80mW 119MHz
119MHz 400mW
1.5mx3.75m footprint (4.5x11.5)
Femtolasers Oscillator Femtosource Scientific
20s (chirped mirrors)
Stretcher
DAZZLER
20 mJ, 120 Hz
RGA Regen Amp
5W, 119MHZ
Spectra Physics MILLENIA Vs
JEDI 1 100 mJ,120 Hz
1mJ, 120Hz
Pre-Amp 4-pass Bowtie
Amplifiers are not cryo-cooled IR stability
lt1rms (short term)
80 mJ, 120 Hz
gt20mJ, 120Hz
Amplifier 2-pass Bowtie
JEDI 2 100 mJ,120 Hz
To cathode
Compressor
THG
gt25mJ, 120Hz
gt2.5mJ, 120Hz
gt40mJ, 120Hz
100 mJ, 120 Hz
6Thales Drive Laser System
7Cathode Launch System Design
- Grazing incidence vs. normal incidence
- Grazing incidence
- Advantages
- No in-vacuum mirrorgt no wake
- Requires no space in gun-to-linac region
- Increased QE for P-polarization
- Disadvantages
- Requires grating to tilt the beam without
introducing temporal slew and to produce round
beam. Grating has less than 50 efficiency - Large bandwidth with grating causes chromatic
aberration - Dispersed beam requires large optics (expensive!)
- Limited/complicated adjustment of beam size on
cathode - Low damage threshold of grating in UV
8Cathode Launch System Design
- Grazing incidence vs. normal incidence
- Normal incidence
- Advantages
- Simple launch optics
- Launch optics allow continuous variation the beam
size on the cathode - Easy to preserve required temporal shape
- Disadvantages
- In-vacuum mirror causes transverse wake
- Lower QE
- Requires space in the gun-to-linac region
- In-vacuum mirror requires careful design
9Normal vs Grazing Incidence
- Grazing incidence optics add risk to laser
shaping - Wakes from dual in-vacuum mirrors tolerable
We have changed the design to normal incidence
10Preliminary Gun Design for Normal Incidence
- Layout of Laser from Injection Mirror to Cathode
gun solenoid
cathode
laser injection cross
vacuum valve
drawing compliments of R.F. Boyce T. Osier
11Optical Design of the Transport and Launch System
- System uses the aspheric beam shaper which
transforms Gaussian beam into flat-top - System allows continuous adjustment of the beam
size on the photocathode - Spatial Shaper and Zoom system for beam diameter
adjustment are located in the laser bay upstairs - Shaper output is imaged with adjustable
magnification to the input of the relay system
that images it to the photocathode through the
transport tube
12Layout
Vacuum cell
Zoom
Beam shaper UV converter
Virtual Cathode
Transport tube
Table in the tunnel
Steering system
Photocathode
Active Steering Stabilization
13Beam Profile on the CathodeZEMAX Modeling
14Beam Profile on the CathodeZEMAX Modeling
15Adjustment of the Beam Diameter
16Beam Size on the vacuum mirror
10mm
10mm
10mm
Radius on the cathode 1.5mm
Radius on the cathode 0.6mm
Size of the vacuum mirror 14mm
17Photocathode Launch System
- Optical system provides flat-top beam on the
cathode - System allows continuous adjustment of the beam
radius on the photocathode from 0.6 to 1.5mm.
Smaller (than 0.6mm) beam size can be achieved by
using smaller aperture after the beam shaper - Design avoids small beam size on optics, which
could cause damage
18Transport Tubes Installation
19Transport Tubes Installation
20Transport Tubes in the Vault
21Response to the April FAC Recommendations
- Strengthening of the laser team
- The LCLS Laser Group leader Bill White started
in May - Long term staffing plan for the group has been
developed - One engineer was hired
22Response to the April FAC Recommendations
- Coordination of the laser RD activities
- Coordination of the efforts of LLNL and ANL is
centralized in the LCLS Laser Group. - As design elements are completed at LLNL and ANL,
they are incorporated into the final design which
is then reviewed by all interested parties. - Purchase of the second laser
- The purchase of a second laser is not in the
current baseline, but we hope to get it in the
future - Laser Bay has space and power for two lasers
23Summary
- First LCLS injector item Laser transport tubes
were installed - Design of the gun has been changed to normal
incidence. It significantly simplifies the
optical set-up and the makes beam shaping less
problematic - Manufacturing of the Drive Laser and RD work
according to the schedule