Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Linac Coherent Light Source Update
John N. Galayda
22 July 2002
Project scope
Cost estimate
DOE Review 23-25 April - results
Future
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
LINAC COHERENT LIGHT SOURCE
I-280
Sand Hill Rd
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
The LCLS produces extraordinarily bright
pulses of synchrotron radiation in a process called
“self-amplified spontaneous emission” (SASE). In this
process, an intense and highly collimated electron
beam travels through an
Saturation
NSNSNSN
undulator magnet.
SNSNSNS
The alternating north and south poles of the magnet
force the electron beam to travel on an approximately
sinusoidal trajectory, emitting synchrotron radiation as
it goes. The electron beam and its synchrotron
radiation are so intense that the electron motion is
modified by the electric and magnetic fields of its own
emitted synchrotron light. Under the influence of both
the undulator magnet and its own synchrotron
radiation, the electron beam is forced to form
micro-bunches,
separated by a distance equal to the wavelength of the
emitted radiation. These micro-bunches begin to
radiate as if they were single particles with immense
charge. Since they are regularly spaced, the radiation
from the micro-bunches has enhanced temporal
coherence. This is indicated by the “smoothing out” of
the instantaneous synchrotron radiation power (shown
Undulator
in the three plots to the right) as the
Magnet
SASE process develops.
Electron
Bunch
BESAC 22 July 2002
LCLS Update
Exponential
Gain Regime
Undulator Regime
N S N S N S N SN S N S N S N SN S N S N S N S N S N S N S N S N S N S N S N S N SN S N S N S N S
SNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSNSN
John N. Galayda
galayda@slac.stanford.edu
Coherent
Synchrotron
Radiation
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Selected LCLS Baseline Design Parameters
Fundamental FEL Radiation Wavelength
Electron Beam Energy
Normalized RMS Slice Emittance
Peak Current
Bunch/Pulse Length (FWHM)
Relative Slice Energy Spread @ Entrance
Saturation Length
FEL Fundamental Saturation Power @ Exit
FEL Photons per Pulse
Peak Brightness @ Undulator Exit
Transverse Coherence
RMS Slice X-Ray Bandwidth
RMS Projected X-Ray Bandwidth
1.5
14.3
1.2
3.4
230
<0.01
87
8
1.1
0.8
Full
0.06
0.13
15
4.5
1.2
3.4
230
0.025
25
17
29
0.06
Full
0.24
0.47
Å
GeV
mm-mrad
kA
fs
%
m
GW
1012
1033 *
%
%
* photons/sec/mm2/mrad2/ 0.1%-BW
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
LCLS R&D Collaboration
FEL Theory, FEL Experiments, Accelerator R&D, Gun Development, Undulator R&D
LLNL
UCLA
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
LCLS R&D, Preconceptual Design Organization
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
LCLS Project Engineering Design Organization
Project Management
John Galayda - Project Director
L. Klaisner, Chief Engineer
UCLA
FEL Physics
.
C. Pellegrini, UCLA
H. D. Nuhn, SLAC
Institutional Liaison-System Managers
John Arthur, SLAC-SSRL
ES&H: Ian Evans
SLAC Radiation Physics:
S. Rokni, S. Mao, W. R. Nelson, A. Prinz
Electron Beam
Systems
Injector
Jim Clendenin, SLAC
QA
PMCS
Photon Beam
Systems
Conventional Facilities
David Saenz, SLAC
X-ray Transport, Optics,Diagnostics
A. Wootton
R. Bionta, Deputy
.
LLNL
Linac
Vinod Bharadwaj, SLAC
X-ray Endstation Systems
Jerry Hastings, SLAC-SSRL
Undulator
Efim Gluskin
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Project Description
Electron Beam Handling Systems
1.2.1 Injector
Photocathode gun and drive laser
150 MeV linac
Located in Sector 20 off-axis injector spur
RF
Gun
Gun-to-Linac
Cathode Load
Lock
L0 Linacs
L0-1
Gun Solenoid
L0-2
Linac Solenoid
Matching Section
Scale:
5 meters
Quadrupole,
typ.
RF Transverse
Deflector
DL1 Bend
Linac Center
Line
Sector 21-1B
Sector 20 Linacs
Emittance
Wire Scanners
BESAC 22 July 2002
LCLS Update
Energy Wire
Scanner & OTR
Straight Ahead
Tune-Up Dump
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Project Description
1.2.2 Linac
X-band RF
Bunch Compressor 1, 250 MeV
Superconducting wiggler
Bunch Compressor 2, 4.5 GeV
Reconfiguration of transport to Final Focus Test Beam Area
rf
gun
7 MeV
Linac-X
Linac-1 L =0.6 m
L =9 m
Linac-0
L =6 m
...existing linac
21-1b
21-1d
DL-1
L =12 m
150 MeV
BESAC 22 July 2002
LCLS Update
X
BC-1
L =6 m
250 MeV
Linac-3
L =550 m
Linac-2
L =330 m
21-3b
24-6d
SLAC linac tunnel
25-1a
30-8c
BC-2
L =22 m
4.54 GeV
14.35 GeV
undulator
L =120 m
DL-2
L =66 m
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
CSR Micro-bunching and Projected Emittance Growth
14.3 GeV at undulator entrance
230 fsec
x versus z without SC-wiggler
projected emittance growth is simply
‘steering’ of bunch head and tail
0.5 mm
x versus z with SC-wiggler
Workshop in Berlin, Jan. 2002 to
benchmark results (www.DESY.de/csr/)
– follow-up meeting 1-5 July, Sardinia
BESAC 22 July 2002
LCLS Update
‘slice’ emittance is not altered
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Project Description
1.2.3 Undulator Systems
121 meter undulator channel, housed in extended FFTB
Diagnostics for x-ray beam and electron beam
Additional 30 meters of space for future enhancements (seeding, slicing,
harmonics)
3420
421
187
UNDULATOR
11055 mm
Beam Position Monitor
Horizontal Steering Coil
Vertical Steering Coil
BESAC 22 July 2002
LCLS Update
Quadrupoles
X-Ray Diagnostics
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Horizontal Trajectory
2.0
Microns
Horizontal Trajectory(µ)
Magnetic Measurement of the Prototype
1.0
0.0
-1.0
-2.0
-800
BESAC 22 July 2002
LCLS Update
-400
0
Z(mm)
400
John N. Galayda
galayda@slac.stanford.edu
800
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Project Description
1.3 Photon Beam Handling Systems
1.3.1 X-ray Transport, Optics and Diagnostics
Front end systems – attenuators, shutters, primary diagnostics
Optics – the prerequisites for LCLS experiments
Grazing incidence mirror to suppress 3rd harmonic
KB pair, refractive optics
Monochromators
Beam splitter
1.3.2 X-ray endstation systems Hutches, Personnel Protection
Computer facilities for experiments
Laser for pump/probe experiments
Detectors matched to LCLS requirements
Essential Infrastructure for the LCLS Experimental
Program
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
X-ray Optics for the LCLS
Objectives
To transport the photon beam to diagnostics and optics stations
To provide the diagnostics necessary to characterize the photon
beam
To provide the optics necessary to demonstrate the capability to
process the photon beam
Requirements
Originally distilled by the working group from the ‘first experiments’
publication, and presentations
LLNL
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Optics Requirements
Focusing: Atomic physics, plasma physics, bioimaging
0.1-1 mm over full energy range
Monochromatization: Plasma physics, materials
science
Resolution of 10-3 - 10-5 at 8 keV
Harmonic control: Atomic physics, materials science
Ratio of higher harmonics to fundamental less than 10-6
Photon pulse manipulation: Materials science
Split and delay over the range 1 ps to 500 ps
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
There are major technical challenges
General
Extreme fluences
maintaining optics for more than 1 pulse
Extremely small temporal and spatial characteristics
maintaining coherence during beam transport and manipulation
high resolution diagnostics
Parameters may vary pulse-to-pulse – need data on every pulse
Windowless operation required at 0.8 keV
Focusing, imaging, data acquisition, spectroscopy, etc. push state-of-the-art
To deal with the fluences, the following strategies are adopted
a far field experimental hall to reduce energy densities by natural divergence
a gas absorption cell and solid attenuator, to attenuate by up to 104
low-Z optics that are damaged least
grazing incidence optics that increase the optical footprint and reflect most
incident power
LLNL
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
The fluence poses the primary challenge
FEE
Hall A
Hall B
LLNL
• In Hall A, low-Z materials will accept even normal incidence. The fluences in Hall B are sufficiently
low for standard optical solutions. Even in the Front End Enclosure (FEE), low Z materials may be
possible at normal incidence above ~4 keV, and at all energies with grazing incidence. In the FEE, gas
is required for attenuation at < 4 keV
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
LCLS Science Program based on the SSRL Model
Experiment Proposals will be developed by leading research
teams with SSRL involvement
Proposals will be reviewed by the LCLS Scientific Advisory
Committee
Research teams secure outside funding with SSRL participation
and sponsorship as appropriate
SSRL will manage construction
Provides cost and schedule control, rationalized design
Provides basis for establishing maintenance and support
infrastructure
SSRL will partner with research teams to commission endstations
“General user” mode with beam time allocation based on SAC
recommendations
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Project Description
1.4 Conventional Facilities
Final Focus Test Beam Extension (30m beamline extension)
Hall A (30mx50m)
Hall B (35mx55m)
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
LCLS Cost Estimate
Costs collected at level 6 of the WBS
Labor in person-weeks
Labor type
Collaborating organization
Purchased materials and services
Assessment of Risk
Costs were collected in base year dollars (FY02)
Costs include:
Labor burden
Indirect costs
Contingency (listed separately)
Did not include inflation
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Funding Profile
LCLS Funding Profile
2-May-02
FY2003
PED
Long Lead
Construction
TEC
R&D
Pre-Ops
Spares
OPC
Total ahead
BESAC 22 July 2002
LCLS Update
$6.0
$6.0
FY2004
$15.0
FY2005
$10.0
$29.9
$15.0
$39.9
$4.0
$4.0
FY2006
$6.0
$4.0
$43.9
FY2008
$2.5
$58.1
$60.6
$3.5
$4.0
$19.0
FY2007
$3.5
$64.1
$71.5
$71.5
$7.7
$2.0
$9.7
$81.2
Total
$28.0
$28.0
$33.5
$29.9
$157.6
$221.0
$20.0
$6.0
$26.0
$54.0
$8.0
$31.2
$8.0
$47.2
$268.2
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Costs by System
1.4
Conventional
Facilities
19%
1.3 Photon
Beam Handling
Systems
23%
BESAC 22 July 2002
LCLS Update
1.1
Management
6%
1.2 Beam
Generation
52%
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Costs by Collaborating Institution
Total Project
Technical Components
ANL
25%
LLNL
14%
BESAC 22 July 2002
LCLS Update
ANL
34%
SLAC
48%
SLAC
61%
LLNL
18%
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Department of Energy Review 23-25 April 2002
Review of Conceptual Design
http://www-ssrl.slac.stanford.edu/lcls/CDR/
Prerequisite for Critical Decision 1, Approval of Preliminary Baseline
Range
Charge to Committee
Is the conceptual design sound and likely to meet the technical
performance requirements?
Are the project’s scope and specifications sufficiently defined to
support preliminary cost and schedule estimates?
Are the cost and schedule estimates credible and realistic for this
stage of the project? Do they include adequate contingency margins?
Is the project being managed(I.e., properly organized, adequately
staffed) as needed to begin Title I design?
Are the ES&H aspects being properly addressed given the project’s
current stage of development?
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Department of Energy Review, 23-25 April 2002
17 reviewers, 6 DOE observers
50 presentations by about 30 speakers
Reviewer Subpanels:
Accelerator Physics – Sam Krinsky, BNL
Injector/Linac – Richard Sheffield, LANL + George Neil, JLAB
Undulator – Kem Robinson, LBNL + Pascal Elleaume, ESRF
Photon Beam Systems – Steve Leone, U of CO + Dennis Mills, ANL
Controls Systems – Dave Gurd, ORNL
Conventional Facilities- Valerie Roberts, LLNL + Jim Lawson, ORNL
Cost/Schedule – John Dalzell, PNNL
Project Management – Jay Marx, LBNL+E. DeSaulnier + Ben Feinberg,
LBNL
ES&H – Frank Kornegay, ORNL + Clarence Hickey, DOE/SC
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Department of Energy Review, 23-25 April 2002
CDR is superb
Cost estimate is credible
On track for approval of CD-1 Summer 2002
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Construction Strategy
2003 – Project Engineering Design Begins
$6M budget
Prepare for Long-lead procurements in 2005
Undulator
Gun Laser
Injector Linac Systems
Spring 2003 – review of plans for long lead procurements
CD-2A Go-ahead required
Spring 2004 – Complete Preliminary Design of LCLS
CD-2 requirements complete for entire project
October 2004 – begin long-lead procurements
Summer 2005 – Critical Decision 3 – Approve start of
construction
Winter 2007 – Begin FEL commissioning
October 2008 – Project Complete
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
The Collaboration is ready to go-
Gun Design
Cost-effective magnet fabrication
techniques developed for NLC
BESAC 22 July 2002
LCLS Update
Undulator Prototype
Optics Fabrication Techniques
Chicane for advanced accelerator R&D
with ultrashort electron bunches
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
Upcoming Workshops
Planning Workshop for the LCLS Experiment Program
7-8 October 2003, SSRL user meeting
Plan for early use of the LCLS
Define areas for R&D leading to experiment proposals
Kick off proposal preparation process
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
International X-FEL Collaboration Workshop
To be be scheduled late October
Define areas of common interest, collaborative activity
Short pulse diagnostic and experiment techniques
Optics
A natural sequence for LCLS/TESLA Collaboration
SLAC Sub-Picosecond Photon Source, 2003-2006
TTF-II
LCLS
TESLA X-FEL
Other opportunities for US-Europe-Asia collaboration
will be explored
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
News from DESY
DESY, TESLA
German Science Council Endorses TESLA
Very strong support of TESLA XFEL, Collider
Endorses physical separation of Collider and XFEL
http://WWW.WISSENSCHAFTSRAT.DE/presse/pm_2002.htm
Calls for Technical Design Report – faster-track, scaled-down XFEL
5 undulators
20 GeV linac
~ € 530M (Materials & purchased services only, no overhead)
First use of a SASE FEL to do an atomic physics experiment
TESLA Test Facility, photoionization in xenon clusters
http://wwwsis.lnf.infn.it/tesla2001/programme.htm
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu
Linac Coherent Light Source
Stanford Synchrotron Radiation Laboratory
Stanford Linear Accelerator Center
End of Presentation
BESAC 22 July 2002
LCLS Update
John N. Galayda
galayda@slac.stanford.edu