Excitements and Challenges for Future Light Sources Based on X-Ray FELs 26th ADVANCED ICFA BEAM DYNAMICS WORKSHOP ON NANOMETRE-SIZE COLLIDING BEAMS Kwang-Je Kim Argonne National Laboratory and The University of Chicago Lausanne, Switzerland September 2-6, 2002
SASE FELs Saturation Saturation Exponential Exponential Gain Regime Gain Regime Undulator Regime Undulator Regime 1 % of X-Ray Pulse 1 % of X-Ray Pulse Electron Bunch Electron Bunch Micro-Bunching Micro-Bunching
Z=25 m Transverse Coherence Z=37.5 m Z=50 m Z=62.5 m Z=75 m Z=87.5 m m Courtesy of Sven Reiche, UCLA
Peak Brightness Enhancement From Undulator To SASE B = #of photons (Ω i - phase space area) Ω x Ω y Ω z Undulator SASE Enhancement Factor # of photons αν e αν e N l c N lc ~ 10 6 Ω ( λ 2) 2 x Ω y (2πε x ) (2πε y ) 10 2 Ω Z ω ω σ Z = 10 3 10 ps c ω ω σ Z = 10 3 100 fs 10 2 c compressed l c -coherence length
Projects: TESLA 400 m X-ray Laser Laboratory 4.5 km 3.9 km Main tunnel
LINACINAC COHERENT LIGHTIGHT SOURCEOURCE 2 Km 0 Km 3 Km
LCLS: Parameters & Performance FEL Radiation Wavelength 15.0 1.5 Å Electron Beam Energy 4.54 14.35 GeV Repetition Rate (1-bunch) 120 120 Hz Single Bunch Charge 1 1 nc Normalized rms Emittance 2.0 1.5 mm-mrad Peak Current 3.4 3.4 ka Coherent rms Energy Spread <2 <1 10 3 Incoherent rms Energy Spread <0.6 <0.2 10 3 Undulator Length 100 100 m Peak Coherent Power 11 9.3 GW Peak Spontaneous Power 8.1 81 GW Peak Brightness * 1.2 12 10 32 * photons/sec/mm 2 /mrad 2 /0.1%-BW
Performance Characteristics Peak and time averaged brightness of the LCLS and other facilities operating or under construction TTF FEL LEUTL LCLS Spontaneous
Self Seeding Scheme for Full Longitudinal Coherence Seed No Seed
Energy E FW /E = 1.0% FW = time 230 fsec t FW x-ray pulse Two-stage undulator for shorter pulse Also a DESY scheme which emphasizes line-width reduction (B. Faatz) Si monochromator (T = 40%) Energy FW < time 10 fsec t FW 1.0 10 10 4 Mitigates e e energy jitter jitter and and undulator wakes time time e UCLA 43 m SASE gain (P( sat sat /10 30 m 52 m /10 3 ) SASE Saturation (23 GW)
LCLS - The First Experiments Team Leaders: Absorption t0 t1 t2 t 3 t 4 t5 Femtochemistry Dan Imre, BNL Resonance Raman t=τ t=0 Nanoscale Dynamics in Condensed Matter Brian Stephenson, APS e 1 as Atomic Physics Phil Bucksbaum, Univ. of Michigan classical plasma Aluminum plasma G=1 dense plasma G =10 G =100 Plasma and Warm Dense Matter Richard Lee, LLNL Report developed by international team of ~45 scientists working with accelerator and laser physics communities high density matter 10-4 10-2 1 10 2 10 4 Density (g/cm -3 ) Structural Studies on Single Particles and Biomolecules Janos Hajdu, Uppsala Univ.
Accelerator System RF Photo-cathode gun Emittance Preservation in Linacs transverse wakefields CSR microbunching instability misalignments & chromaticity Machine Stability jitter tolerance budget simulation of budget
LCLS: System Components 7 MeV σ z 0.83 mm σ δ 0.2 % Linac-0 L =6 m RF Gun new new 150 MeV σ z 0.83 mm σ δ 0.10 % Linac-1 L =9 m Linac-X L =0.6 m 250 MeV σ z 0.19 mm σ δ 1.8 % Linac-2 L =330 m 4.54 GeV 4.54-14.35 GeV σ z 0.023 mm σ z 0.023 mm σ δ 0.76 % σ δ 0.02 % Linac-3 Undulator L =550 m L =121.8 m 1.5 Å 8 GW σ z 0.023 mm 15 Å 17 GW σ z 0.023 mm...existing linac 21-1b 1b 21-1d 1d X 21-3b 24-6d 25-1a 30-8c DL-1 L =12 m BC-1 L =6 m BC-2 L =22 m DL-2 L =66 m Beam Dump SLAC linac tunnel Undulator Hall Exp Halls
RF Photo-Cathode Gun Half Cell Laser Port Normalized Normalized Slice Slice Emittance: Emittance: (rms) (rms) Max Max Bunch Bunch Charge: Charge: Bunch Bunch Length: Length: 11 µmrad µmrad 11 nc nc 0.8 0.8 mm mm Full Cell Electron Beam Exit Exit Photocathode 0 1" Scale 2" 3"
e Coherent Synchrotron Radiation (CSR) Induced energy spread breaks achromatic system Causes bend-plane emittance growth (short bunch is worse) Powerful radiation generates energy spread in bends bend-plane emittance growth σ z θ L 0 R λ s Ε/Ε = 0 Ε/Ε < 0 x overtaking length: L 0 (24σ z R 2 ) 1/3 coherent radiation for λ > σ z x x = R 16 (s) E/E
X-band RF used to Linearize Compression (f = 11.424 GHz) S-band RF curvature and 2 nd -order momentum compaction cause sharp peak current spike X-band RF at decelerating phase corrects 2 nd order and allows unchanged z-distribution E/ E /% 4 2 0 2 σ E / E =1.761 % ϕ 1 40 4 0 0.5 1 1.5 3 E/ E /% E =0.2500 GeV, N e =0.625 10 10 4 λ x = λ s /4 2 0 2 ϕ x = π 1 0 1 z /mm I /ka 0.12 0.1 0.08 0.06 0.04 0.02 σ z = 0.8300 mm Slope linearized nd - 0 2 0 2 z /mm 4 σ E / E =1.761 % E =0.2500 GeV, N 4 e =0.625 10 10 0.5 σ z = 0.1996 mm avoid! E/ E /% 2 0 E/ E /% 2 0 I /ka 0.4 0.3 0.2 2 2 0.1 4 0 0.5 1 1.5 n/10 3 4 2 0 2 z /mm 0 2 0 2 z /mm ev x = E 1 ( 1 σ σ ) 0 2 1 λs T566 0 2 3 2π R 56 ( λ λ ) s x 2 1 2 z z Ei 0.6-m m section, 22 MV available at SLAC (200-µm m alignment)
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 µm x versus z with SC-wiggler Workshop Workshop in in Berlin, Berlin, Jan. Jan. 2002 2002 to to benchmark benchmark results results (www.desy.de/csr/( (www.desy.de/csr/) Courtesy Courtesy Paul Paul Emma, Emma, SLAC SLAC slice emittance is not altered
Cell structure of the LCLS undulator line 3420 187 421 UNDULATOR 11055 mm Horizontal Steering Coil Vertical Steering Coil Beam Position Monitor X-Ray Diagnostics Quadrupoles
Start-to-End Tracking Simulations Track entire machine to evaluate beam brightness & FEL space-charge charge Parmela compression, wakes, CSR, Elegant SASE FEL with wakes Genesis Track machine many times with jitter to test stability budget (M. Borland, ANL)
Magnetic Measurement of the Prototype Horizontal Trajectory 2.0 Horizontal Trajectory(µ) Microns 1.0 0.0-1.0-2.0-800 -400 0 Z(mm) 400 800
Potential for Damage to X-Ray Optics LLNL 100 10 undulator FEE exit experimental Hall A hall 1 0.1 0.01 Be C Si W Au 100 1000 10000 Photon energy (ev) experimental hall Hall BB 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
SASE Demonstration Experiments at Longer Wavelengths IR wavelengths: UCLA/LANL (λ = 12µ, G = 10 5 ) LANL (λ = 16µ, G = 10 3 ) BNL ATF/APS (λ = 5.3µ, G = 10, HGHG = 10 7 times S.E.) Visible and UV: TESLA Test Facility (DESY): E e = 390 MeV, L u = 15 m, λ = 42 nm VISA (BNL-LANL-LLNL-SLAC-UCLA): E e = 70 MeV, L u = 4m, λ = 0.8 µ APS LEUTL: E e 700 MeV, L u = 25 m, 120 nm λ 530nm All successful!
Optical Intensity Gain 1. 10 7 1. 10 6 1. 10 5 Intensity [arb. units] 1. 10 4 1. 10 3 100 10 I peak bunch length charge emittance 266 A 0.3 ps 200 pc 8.5 µm 1 energy spread 0.1% L g, theor. 0.59 m 0.1 L g, meas. 0.57 m 0.01 0 5 10 15 20 25 Distance [m] Science, v. 292, pp 2037-2041 (2001)
TTF2: Soft-X ray User Facility / Overview BC 3 BC 2
Properties of SASE FEL radiation: 1) transv. coherence 2) long. coherence 3) fluctuations 1) Transverse coherence should be almost 100 % at saturation Observation of diffraction pattern at TTF FEL: Y [mm] 1 0 1 after double slit after cross 2 0 2 Intensity [arb.units] 6 4 2 0 2 0 2 2 0 2 X [mm] X [mm]
Future Light Sources based on X-ray FELs A leap in electron beam and photon beam technology A leap in x-ray science Proposals around the world for UV and x-ray facilities LCLS turns on in 98
Acknowledgement I thank my colleagues at SLAC, DESY, and ANL for making these excellent VGs available to me!