Presentation is loading. Please wait.

Presentation is loading. Please wait.

Temporal overlapping for HHG- seeded EUV-FEL operation by using EOS-based timing-drift controlling system H. Tomizawa 1,4 *, S. Matsubara 1, T. Togashi.

Published byAmber Norris Modified over 8 years ago

Similar presentations

Presentation on theme: "Temporal overlapping for HHG- seeded EUV-FEL operation by using EOS-based timing-drift controlling system H. Tomizawa 1,4 *, S. Matsubara 1, T. Togashi."— Presentation transcript:

1 Temporal overlapping for HHG- seeded EUV-FEL operation by using EOS-based timing-drift controlling system H. Tomizawa 1,4 *, S. Matsubara 1, T. Togashi 1, E. J. Takahashi 2, K. Midorikawa 2, M. Aoyama 3, K. Yamakawa 3, T. Sato 4, 5, A. Iwasaki 5, S. Owada 5, K. Yamanouchi 5, K. Togawa 4, 1, T. Hara 4, 1, K. Ogawa 4, T. Ohshima 4, 1, Y. Okayasu 1, 4, Y. Otake 4, 1, H. Tanaka 4, 1, T. Tanaka 4, 1, T. Watanabe 1, 4, M. Yabashi 1,4, and T. Ishikawa 4 1. Japan Synchrotron Radiation Research Institute 2. RIKEN Advanced Science Institute 3. Japan Atomic Energy Agency 4. RIKEN SPring-8 Center 5. The University of Tokyo

2 Overview & History EOS Setup to improve the seeded FEL performance Recent Results Summary “HHG seeded EUV-FEL operation at SCSS Test Accelerator” Outline

3 Development history of X-ray light source Seeded X-ray FELs “SACLA” XFEL (JAPAN) “SPring-8” 3 rd generation SR-Ring (JAPAN)

4 Spontaneous radiation e-beam 電子銃 加速管 e-gunAcceleratorUndulator X-ray laser ☺ Intense light pulse (  J ~ mJ ) * ☺ Wide wavelength range ( THz ~ x-ray ) ☺ Short pulse ( 10 fs ~ 1 ps ) ☺ Spatial coherence ☹ Shot-to-shot fluctuation * FLASH (Germany), SCSS (Japan), LCLS (USA), SACLA (JAPAN), … Self-amplification of spontaneous emission (SASE)

5 SCSS EUV-FEL Accelerator SCSS accelerator ( 250MeV, 50-60nm ) – EUV-FEL machine is operated for user experiment. – Development of HHG-seeded FEL 5 Electron Gun Bunch Compressor C-band Accelerator Undulator

6 Fluctuating spectra – SASE operation at SCSS SASE-FEL starts up from noise Energy spectra and temporal profiles are fluctuating shot-to-shot! (originated from the SASE process) External seeding scheme is one of the solution to suppress shot-noise for reliable full-coherent light source (user operation).

7 Our history of Seeding Developments DateEventConditionReference June 2006 The first SASE amplification with our new machine concept 250 MeV, 49nm Dec. 2006 Seeding at 160 nm 150 MeV, HHG 5 th G. Lambert et al., Nat. Physics 4, 296 (2008) Sept. 2007 SASE saturation250 MeV, 50~60nm T. Shintake et al., Nat. Photonics. 2, 559 (2008) Oct. 2010 Seeding at 61 nm Hit rate: ~0.3% Pulse energy : ~2  J 250 MeV, 300 fs HHG 13 th T. Togashi, et al., Opt. Exp. 19, 317 (2011) March 2011 The first test of Arrival time monitor (relative timing btw. e-bunch and HHG with EO sampling) H. Tomizawa, BIW2012, Newport News, VA (2012) July 2012 Seeding at 61 nm with EO sampling Hit rate: ~30% Pulse energy : ~20  J 250 MeV, 600 fs HHG 13 th H. Tomizawa, et al., LINAC2012, Tel-Aviv (2012)

8 Task force in our collaboration for HHG-seeding Supports for this projects: RIKEN/JASRI XFEL project SCSS test accelerator operation team (Engineers) Financial supports : RIKEN extreme photonics MEXT X-ray free electron laser utilization research (The University of Tokyo) Japan Atomic Energy Agency, Quantum Beam Science Directorate A. Iwasaki K. Ogawa, Y. Okayasu, H. Tomizawa, T. Togashi, T. Sato, S. Owada T. Watanabe, E. J. Takahashi, S. Matsubara

9 6D phase space overlap for seeded FEL 9 Size (x, y) FWHM Time FWHM Wavelength ( Energy) Electron bunch ~ 500  m~ 600 fs61.2 nm HHG seed pulse ~ 1 mm~ 50 fs61.4 nm 6D Phase Space X,  x Y,  y t, E

10 Seeding results at 61 nm in 2010 (1) 61nm-2nJ HHG @ Undulator HHG Spectrum ← Temporal overlap ↓ Spatial overlap

11 Spectra of sequent 50 shots T. Togashi et. al., Optics Express, Vol. 19 Issue 1, pp.317-324 (2011) Trend graph of peak intensity Hit rate 〜0.3% (Intensity >4σ of SASE) SASE FEL: 0.7  J Seeded FEL: 1.3  J but, hit rate ~ 0.3% Duration of seeded operation < 10 min SASE FEL: 0.7  J Seeded FEL: 1.3  J but, hit rate ~ 0.3% Duration of seeded operation < 10 min Seeding results at 61 nm in 2010 (2)

12 Improvement of Hit Rate (~ 2012 ) (1) 61nm-2nJ HHG@Undulator Arrival time monitor by means of EO-sampling implemented

13 Principle of EOS ( Electro-Optic Sampling ) Pockel’s effect (ZnTe) Z(110) (001) p p By detecting the retardation (Modulation of Polarization), we can know the temporal information of electron bunch (Electric field). Spectral Decoding

14 61nm-2nJ HHG@Undulator Late Early Wavelength (time) Improvement of Hit Rate (~ 2012 ) (2)

15 Relative timing-drift monitored by EOS “Relative” timing drift between the electron bunch and the laser pulse The spectra of EOS signal pulses decoded as the timing shifts from the best seeding condition (On-time) Late +1 ps Early -1 ps The arrival-time drift of electron bunch with respect to the central wavelength of EO-probe pulse: ~50 ps for ½ day The arrival-time drift is calculated automatically with the computer program in terms of the peak position of the EOS signals. On-time

16 Seeded FEL Performances (2012) (1) Seeded SASE SASE+4  SASE+6  Seeded SASE SASE+4  SASE+6  +4  hit rate: 24% Improved by 100! Seed HHG: 2 nJ x 10 4 gain Improved by 10! +4  hit rate: 24% Improved by 100! Seed HHG: 2 nJ x 10 4 gain Improved by 10!

17 Seeded FEL Performances (2012) (2) The correlation data plot between the normalized intensity and central wavelength for 10000 shot data The correlation data plot between the normalized intensity and central wavelength for 10000 shot data The standard deviation of the central wavelength of SASE (blue) and the seeded pulse (red) were 0.15 nm and 0.073 nm, respectively.

18 Seeded FEL Performances (2012) (4)

19 Improvements of FEL Performances (2010  2012) w/o feedback w/ feedback Previous result (2010) This result (2012) By using the EOS-based timing-drift system, the HH seeded FEL succeed to continuously operate about a half day which is the machine time of SCSS accelerator with 20-30% hit rate. ・ Seeded FEL output was 1.3  J ・ The seeding operation was only obtained less than 10 minutes.

20 Summary Recent R&D to improve the hit rate at the SCSS FEL test accelerator has proven the capability of stable HHG-seeded FEL. – EOS-based timing-drift controlling system was constructed for the continual seeded FEL operation.  The seeding laser pulse has large timing drift with respect to electron bunch of ~50 ps for ½ day.  The relative timing-drift controlling system was needed to stable operation. – Improved HHG seeded FEL operation was succeed with 20  J and ~30% hit-rate.

Download ppt "Temporal overlapping for HHG- seeded EUV-FEL operation by using EOS-based timing-drift controlling system H. Tomizawa 1,4 *, S. Matsubara 1, T. Togashi."

Similar presentations

X-ray Free Electron lasers Zhirong Huang. Lecture Outline XFEL basics XFEL basics XFEL projects and R&D areas XFEL projects and R&D areas Questions and.

X-ray Free Electron lasers Zhirong Huang. Lecture Outline XFEL basics XFEL basics XFEL projects and R&D areas XFEL projects and R&D areas Questions and.
Schemes for generation of attosecond pulses in X-ray FELs E.L. Saldin, E.A. Schneidmiller, M.V. Yurkov The potential for the development of XFEL beyond.

Schemes for generation of attosecond pulses in X-ray FELs E.L. Saldin, E.A. Schneidmiller, M.V. Yurkov The potential for the development of XFEL beyond.
Ultrafast Experiments Hao Hu The University of Tennessee Department of Physics and Astronomy, Knoxville Course: Advanced Solid State Physics II (Spring.

Ultrafast Experiments Hao Hu The University of Tennessee Department of Physics and Astronomy, Knoxville Course: Advanced Solid State Physics II (Spring.
LC-ABD P.J. Phillips, W.A. Gillespie (University of Dundee) S. P. Jamison (ASTeC, Daresbury Laboratory) A.M. Macleod (University of Abertay) Collaborators.

LC-ABD P.J. Phillips, W.A. Gillespie (University of Dundee) S. P. Jamison (ASTeC, Daresbury Laboratory) A.M. Macleod (University of Abertay) Collaborators.
05/03/2004 Measurement of Bunch Length Using Spectral Analysis of Incoherent Fluctuations Vadim Sajaev Advanced Photon Source Argonne National Laboratory.

05/03/2004 Measurement of Bunch Length Using Spectral Analysis of Incoherent Fluctuations Vadim Sajaev Advanced Photon Source Argonne National Laboratory.
Soft X-ray light sources Light Sources Ulrike Frühling Bad Honnef 2014.

Soft X-ray light sources Light Sources Ulrike Frühling Bad Honnef 2014.
Professor David Attwood / UC Berkeley / ICTP-IAEA School, Trieste, November 2014 ICTP_Trieste_Lec1_Nov2014.pptx Introduction to Synchrotron Radiation and.

Professor David Attwood / UC Berkeley / ICTP-IAEA School, Trieste, November 2014 ICTP_Trieste_Lec1_Nov2014.pptx Introduction to Synchrotron Radiation and.
Approaches for the generation of femtosecond x-ray pulses Zhirong Huang (SLAC)

Approaches for the generation of femtosecond x-ray pulses Zhirong Huang (SLAC)
E. Schneidmiller and M. Yurkov (SASE & MCP) C. Behrens, W. Decking, H. Delsim, T. Limberg, R. Kammering (rf & LOLA) N. Guerassimova and R. Treusch (PGM.

E. Schneidmiller and M. Yurkov (SASE & MCP) C. Behrens, W. Decking, H. Delsim, T. Limberg, R. Kammering (rf & LOLA) N. Guerassimova and R. Treusch (PGM.
2004 CLEO/IQEC, San Francisco, May 15-21 Optical properties of the output of a high-gain, self-amplified free- electron laser Yuelin Li Advanced Photon.

2004 CLEO/IQEC, San Francisco, May Optical properties of the output of a high-gain, self-amplified free- electron laser Yuelin Li Advanced Photon.
Hard X-ray FELs (Overview) Zhirong Huang March 6, 2012 FLS2012 Workshop, Jefferson Lab.

Hard X-ray FELs (Overview) Zhirong Huang March 6, 2012 FLS2012 Workshop, Jefferson Lab.
The BESSY Soft X-Ray SASE FEL (Free Electron Laser)

The BESSY Soft X-Ray SASE FEL (Free Electron Laser)
A. Zholents, July 28, 2004 Timing Controls Using Enhanced SASE Technique *) A. Zholents or *) towards absolute synchronization between “visible” pump and.

A. Zholents, July 28, 2004 Timing Controls Using Enhanced SASE Technique *) A. Zholents or *) towards absolute synchronization between “visible” pump and.
Juhao Wu Feedback & Oct. 12 – 13, 2004 Juhao Wu Stanford Linear Accelerator Center LCLS Longitudinal Feedback with CSR as Diagnostic.

Juhao Wu Feedback & Oct. 12 – 13, 2004 Juhao Wu Stanford Linear Accelerator Center LCLS Longitudinal Feedback with CSR as Diagnostic.
Bunch Length Measurements at the Swiss Light Source (SLS) Linac at the PSI using Electro-Optical Sampling A.Winter, Aachen University and DESY Miniworkshop.

Bunch Length Measurements at the Swiss Light Source (SLS) Linac at the PSI using Electro-Optical Sampling A.Winter, Aachen University and DESY Miniworkshop.
FLASH Experiments with Photons High intensity laser light in the VUV spectral region Harald Redlin; HASYLAB.

FLASH Experiments with Photons High intensity laser light in the VUV spectral region Harald Redlin; HASYLAB.
UCLA The X-ray Free-electron Laser: Exploring Matter at the angstrom- femtosecond Space and Time Scales C. Pellegrini UCLA/SLAC 2C. Pellegrini, August.

UCLA The X-ray Free-electron Laser: Exploring Matter at the angstrom- femtosecond Space and Time Scales C. Pellegrini UCLA/SLAC 2C. Pellegrini, August.
SLAC XFEL Short Bunch Measurement and Timing Workshop 1 Current status of the FERMI project (slides provided by Rene Bakker) Photoinjector laser system.

SLAC XFEL Short Bunch Measurement and Timing Workshop 1 Current status of the FERMI project (slides provided by Rene Bakker) Photoinjector laser system.
John Arthur LCLS Diagnostics and Commissioning September 22, 2004 Summary of Related Topics from the Miniworkshop on.

John Arthur LCLS Diagnostics and Commissioning September 22, 2004 Summary of Related Topics from the Miniworkshop on.
Random phase noise effect on the contrast of an ultra-high intensity laser Y.Mashiba 1, 2, H.Sasao 3, H.Kiriyama 1, M.R.Asakawa 2, K.Kondo 1, and P. R.

Random phase noise effect on the contrast of an ultra-high intensity laser Y.Mashiba 1, 2, H.Sasao 3, H.Kiriyama 1, M.R.Asakawa 2, K.Kondo 1, and P. R.

Similar presentations

Ads by Google