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Issues and Challenges for Short Pulse Radiation Production

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Presentation on theme: "Issues and Challenges for Short Pulse Radiation Production"— Presentation transcript:

1 Issues and Challenges for Short Pulse Radiation Production
Paul Emma Stanford Linear Accelerator Center July 8, 2004

2 -W. Safire, NY Times, March 7, 2004
How Short? …defined by New York Traffic Commissioner T.T. Wiley in 1950 as: “…the time between the light turning green and the guy behind you honking.” -W. Safire, NY Times, March 7, 2004 Several FEL proposals go beyond even this: sub-femtosecond pulses 1-Å radiation GW power levels unprecedented brightness why so short…

3 used spark photography to freeze this ‘ultra-fast’ process
E. Muybridge at L. Stanford in 1878 disagree whether all feet leave the ground during gallop… E. Muybridge used spark photography to freeze this ‘ultra-fast’ process E. Muybridge, Animals in Motion, ed. L. S. Brown (Dover Pub. Co., New York 1957).

4 Coulomb Explosion of Lysozyme (50 fs)
Single Molecule Imaging with Intense X-rays Atomic and molecular dynamics occur at the fsec-scale J. Hajdu, Uppsala U.

5 Time Scales Dt  1 sec 1 femto-second (fs) = 10-15 sec  0.3 m m
1 atto-second (as) = sec  0.3 nm In Neils Bohr’s 1913 model of the Hydrogen atom it takes about 150 as for an electron to orbit the proton. – Nature, 2004

6 Outline Electron bunch limitations Photon pulse limitations
Schemes for short pulse generation SPPS results (Sub-psec Pulse Source) Just a tick: Scientists are using ever-shorter time scales to investigate chemical reactions. Nature, February 26, 2004

7 Electron bunch length is limited by…
Coherent synch. rad. (CSR) in compressors Longitudinal wakefields in linac & undulator Space-charge forces in accelerator System jitter (RF, charge, etc) Try to compress sz in LCLS to 1 mm… CSR: e /e0 = 1 1 nC brightness destroyed CSR: e /e0  14

8 Coherent Synchrotron Radiation in Bends
sz e– Coherent radiation for lr > sz lr R (= L/q) R A. Kabel: MOPKF081 DE/E = 0 lr bend-plane emittance is ruined  DE/E < 0

9 Resistive-Wall Wakefields in Undulator
extreme wake Copper tube

10 Micro-Bunching Instabilities
FEL ‘instability’ needs very “cold” e- beam (small ex,y & E-spread) Cold beam is subject to “undesirable” instabilities in accelerator (CSR, Longitudinal Space-Charge, wakefields) t current modulation 1% 10% Gain=10 Z(k) LCLS simulations (M. Borland) CSR m-bunching Saldin, Schneidmiller, Yurkov TESLA-FEL Can be Landau damped with energy spread

11 How cold is the photo-injector beam?
Parmela Simulation TTF measurement simulation measured M. Hüning, H. Schlarb, PAC’03. 3 keV DE/E Dt (sec) 3 keV, accelerated to 14 GeV, & compressed 36  110-5 Too small to be useful in FEL (no effect on FEL gain when <10-4)

12 ‘Laser Heater’ in LCLS for Landau Damping
Ti:saph 800 nm 1.2 MW Injector at 135 MeV 40 keV rms ‘Laser heater’ suggested by Saldin et al. Laser-e- interaction  800-nm E-modulation (40 keV rms) Heater in weak chicane for time-coordinate smearing Energy spread in next compressors smears m-bunching Huang: WEPLT156, Limborg: TUPLT162, Carr: MOPKF083

13 In LCLS tracking, final energy spread blows up without ‘Laser-Heater’
heater OFF 0.1% heater ON 0.01 % Final longitudinal phase space at 14 GeV for initial 15-mm, 1% modulation at 135 MeV Z. Huang et al., SLAC-PUB-10334, accepted in PR ST AB, June 2004

14 Outline Electron bunch limitations Photon pulse limitations
Schemes for short pulse generation SPPS results (Sub-psec Pulse Source) Just a tick: Scientists are using ever-shorter time scales to investigate chemical reactions. Nature, February 26, 2004

15 FEL pulse duration limited by intrinsic bandwidth
For shorter pulses: shorter wavelength, lr larger r (smaller ex,y) low-gain (large Dw) seeded start-up For X-ray FEL: lr  1 Å, sw/w0  0.04%, st  100 as FEL-type: Nu Lu Dw/w Saturated SASE ~1/r ~20Lg ~r Seeded High-Gain <1/r <20Lg >r Seeded Low-Gain ~1/(4pr) ~2Lg ~4pr

16 Monochromator Pulse Slicing
w t sw /h h sw sm monochromator bandwidth sm/w0 = 10-4, sw/w0 = 510-4, h  2%  st  5 fs S. Krinsky, Z. Huang, PR ST AB, 6, (2003).

17 Outline Electron bunch limitations Photon pulse limitations
Schemes for short pulse generation SPPS results (Sub-psec Pulse Source) Just a tick: Scientists are using ever-shorter time scales to investigate chemical reactions. Nature, February 26, 2004

18 HGHG Saturation at DUVFEL
0.9 ps 0.4 ps 0.3 ps pulse length control with seed laser 266 nm Li-Hua Yu et al. PRL 91, (2003). Ipk = 300 A, sE/E0 = 0.01% Pin = 1.8 MW: sz = 0.6 ps, ge = 2.7 mm, dy/dg = 8.7 Pin = 30 MW: sz = 1.0 ps, ge = 4.7 mm, dy/dg = 3.0

19 Statistical Single-Spike Selection
Un-seeded single-bunch HGHG (8  4  2  1 Å ) 8 Å I8  I18 1 Å 300 as Saldin et al., Opt. Comm., 212, 377 (2002).

20 e- Add thin slotted foil in center of chicane y 2Dx x  DE/E  t
coulomb scattered e- unspoiled e- 2Dx x  DE/E  t 15-mm thick Be foil LCLS PRL 92, (2004). P. Emma, M. Cornacchia, K. Bane, Z. Huang, H. Schlarb, G. Stupakov, D. Walz (SLAC)

21 200 fs DE/E No design changes to FEL – only foil added in chicane
Track 200k macro-particles through entire LCLS up to 14.3 GeV 200 fs DE/E cold e- core passing through slot No design changes to FEL – only foil added in chicane

22 2 fs FWHM Power (GW) z  60 m ~1010 photons x-ray Power
Genesis 1.3 FEL code ~1010 photons x-ray Power 2 fs FWHM (<1 fs possible) Power (GW)

23 800 nm 2 nm, 100 MW, 100 fs Mod. tuned so only high energy e- interact with 2-nm HC FEL radiation Modulator Chicane 2 nm LUX electron beam parameters: e- energy = 3 GeV emittance = 2 mm-mrad energy spread = 0.3 MeV peak current = 500 A ~2x106 photons 110 as 1 nm Generation of Attosecond Pulses… A. Zholents, W. Fawley PRL 92, (2004). MOPKF072

24 300 as 1 GW Saldin et al., Opt. Comm., 237, 153 (2004). Ge
Ti:saph: 800 nm, 2-4 mJ, 5 fs 300 as monochromator to select single pulse monochromator is broadband Ge crystal diffracting from the (1 1 1) lattice planes (pre-monochromator to reduce power) 1 GW Saldin et al., Opt. Comm., 237, 153 (2004).

25 E-SASE (applied to LCLS)
SASE FEL 4 GeV 14 GeV 800-nm modulation (few GW) short pulse train peak current enhanced x7 70 as 24 kA Allows synchronization between laser pulse and x-ray pulse E-SASE (applied to LCLS) A. Zholents (submitted to PRL)

26 Outline Electron bunch limitations Photon pulse limitations
Schemes for short pulse generation SPPS results (Sub-psec Pulse Source) Just a tick: Scientists are using ever-shorter time scales to investigate chemical reactions. Nature, February 26, 2004

27 Short Bunch Generation in the SLAC Linac
1-GeV Damping Ring sz  6 mm SLAC Linac FFTB add 14-meter chicane in linac at 1/3-point (9 GeV) sz 1.1 mm sz  40 mm Existing bends compress to 80 fsec 1.5 Å compression by factor of 500 30 GeV sz  12 mm 1.5% 28.5 GeV 30 kA 80 fs FWHM P. Emma et al., PAC’01

28 Source comparisons SPPS 11025 80 2107 2106 1109 500 1106 100
Peak brightness** Pulse length (fsec) Average flux (photon/sec) Photons per pulse per 0.1% BW Rep. Rate (Hz) Table top laser plasma 1109 500 1106 100 1104 ALS* (streak camera) 51017 4104 2108 2104 ALS slicing (undulator) 11017 (61019) 1105 (3104) 10 (300) ESRF 11024 8104 31010 3107 900 SPPS 11025 80 2107 2106 * streak camera resolution 1 psec, DQe 0.01 ** photons/sec/mm2/mrad2/0.1%-BW J. Hastings, SLAC

29 Dave Fritz, Soo Lee, David Reis
Undulator, view upstream Dave Fritz, Soo Lee, David Reis Undulator parameters: Lu  2.5 m, lu = 8.5 cm, K  4.3, B  0.55 T, Np  30

30 R&D at SPPS Towards X-Ray FELs
 Measure wakefields of micro-bunch  Develop bunch length diagnostics  Study RF phase stability of linac  Measure emittance growth in chicane (CSR)  X-ray optics and transport

31 Wakefield energy-loss used to set and confirm minimum bunch length
sz  40 mm theory meas. K. Bane et al., PAC’03

32 Transition radiation is coherent for /2p > sz (CTR)
P. Muggli, M. Hogan

33 CTR sz  9 mm Gaussian bunch: sz  18 mm
minimum bunch length (with j-jitter) Mylar resonances CTR Autocorrelation Gaussian bunch: sz  18 mm sz  9 mm Dz (mm) P. Muggli, M. Hogan

34 SPPS chicane CSR simulations with 1D model (unshielded)
(good agreement with 3D-model studied by F. Stulle - DESY) 3.4 nC, 9 GeV 9 kA 1 mm FWHM/2.35  40 mm 0.3 kA

35 Bend-Plane Emittance: Chicane ON and OFF
Bend-plane emittance is consistent with calculations and sets upper limit on CSR effect P. Emma et al., PAC’03

36 Concluding Remarks Very short x-ray pulses are key to exploring ultra-fast science at future light sources Linac-based FEL’s offer high power, very high brightness, and possibly sub-femtosecond pulses at ~1-Å wavelengths Advances in ultra-short, high-power table-top lasers will greatly influence future LS designs, as will e- gun development (gex,y < 1 mm) Thanks to the many who contributed to this presentation… Z. Huang, W. Fawley, and A. Zholents

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