Presentation is loading. Please wait.

Presentation is loading. Please wait.

Atomic Physics with VUV-FEL Radiation R. Moshammer MPIK-Heidelberg SASE FEL Radiation (Self Amplification of Spontaneous Emission Free Electron Laser)

Published byEvelyn Leonard Modified over 8 years ago

Similar presentations

Presentation on theme: "Atomic Physics with VUV-FEL Radiation R. Moshammer MPIK-Heidelberg SASE FEL Radiation (Self Amplification of Spontaneous Emission Free Electron Laser)"— Presentation transcript:

1 Atomic Physics with VUV-FEL Radiation R. Moshammer MPIK-Heidelberg SASE FEL Radiation (Self Amplification of Spontaneous Emission Free Electron Laser) Unique Light Sources VUV-FEL User Facilities I. Multi-Photon Processes in Atoms & Molecules Interactions with Molecular Ions Spectroscopy & Ionisation of Ions II.

2 bunch of N e electrons Undulator Synchrotron-Radiation From Synchrotron Radiation to FEL-Light Power  N e

3 bunch of N e electrons Undulator Synchrotron-Radiation From Synchrotron Radiation to FEL-Light Power  N e

4 From Synchrotron Radiation to FEL-Light Undulator Self Amplified Spontaneous Emission (SASE) bunch of N e electrons Power  N e 2 FEL-Radiation

5 measured Sept. 2001 From Synchrotron Radiation to FEL-Light Gain in Quality & Power: 5-8 Orders 5-8 Orders of Magnitudes

6 High-Power Laser versus FEL proposed FEL’s

7 Full coherence:.......  /  10 -4... 10 -8 Photon energies:.....10 eV to 10 keV Pulse width :.........  T < 100 fs Rep. Rate :............. up to 70 kHz Photons / Pulse :.....10 12 Peak-Power :..........MW to GW Intensities:..............I > 10 16 W/cm 2 Non-Linear Processes in Atoms (Molecules) Atomic Reactions with Small Cross-Sections Unique Light Sources

8 Proposed Facilities BESSY: E  < 1 keV SLAC : E  < 8 keV TESLA : E  < 14 keV Daresbury, Spring8,........... Under construction TESLA Test Facility (TTF at DESY Hamburg) Start of user experiments in 2004 E  < 200 eV VUV-FEL User Facilities

9 Hamburg: TESLA Test Facility (TTF)

10

11 Multi-Photon Processes in Atoms & Molecules Interactions with Molecular Ions Spectroscopy & Ionisation of Ions Atomic Physics (Approved TTF - Experiments) Universität Frankfurt:R. Dörner, L. Schmidt, Th. Weber Fritz-Haber Institut Berlin:U. Becker Universität Hamburg:B. Sonntag Max-Planck-Institut Heidelberg:R. Moshammer, A. Dorn, D. Fischer, C.D. Schröter, J. Ullrich Max-Planck-Institut Heidelberg: H.B. Pederson, A. Wolf, D. Schwalm, J. Ullrich Weizmann Institute Rehovot:D. Zajfmann Max-Planck-Institut Heidelberg: J.R. Crespo, J. Braun, J. Bruhns, A. Dorn, R. Moshammer, C.D. Schröter, J. Ullrich Fudan University Shanghai Y. Zou LLNL Livermore P. Beiersdorfer

12 Multi-Photon Processes in Atoms & Molecules Interactions with Molecular Ions Spectroscopy & Ionisation of Ions Atomic Physics

13 Multi-Photon Processes in Atoms Multi-Photon Processes in Atoms & Molecules Interactions with Molecular Ions Spectroscopy & Ionisation of Ions

14 Experimental Approach Supersonic gas jet Atoms, Molecules FEL Spectrometer: Ion-electron coincidence  eV ion energy resolution meV electron resolution Drift Detector position-sensitive, multi-hit Helmholtz coils Reaction-Microscope El. field

15 Ultra high vacuum : p < 10 -11 mbar Ultra cold gas-jet : T < 1 Kelvin Multi-hit detectors :  = 12 cm,  t ~ 10 ns Laser beam Ion-detector Gas-jet Electron-detector Experimental Approach

16 From Single Photons to Many Photons Ionisation of Atoms High Intensity Lasers I = 10 15 W/cm 2 h << I p Many Photons Single Photon h > I p Synchrotron-Radiation Few PhotonsFEL

17 Single Photon From Single Photons to Many Photons Tunneling  10 15 W/cm 2 Electron-Energy E e   Many PhotonsFew Photons ? Dörner (1997)

18 Dörner et al. (2001) From Single to Double Ionization Single Photon P || /a.u. -10 -510 0 5 Many Photons 

19 Single PhotonMany Photons  e2e2 e1e1 e2e2 e1e1 ! well understood ! ! many open questions ! From Single to Double Ionization

20 e - momentum P || (e 1 ) [a.u.] P || (e 2 ) [a.u.] Experiment too many photons classical field  ponderomotive motion Theory (Goreslavski et al.) Exp.: MBI-Berlin, MPI-Heidelberg, Frankfurt, Marburg...... Theory: Becker, Faisal, Taylor, Goreslavski..... Problems:

21 “Few” Photons: FEL - Radiation Helium ponderomotive potential U p  I/  2  0 tt 13 2 + + possible Mechanisms: e.g. E   = 50 eV

22 energy [eV] -24 -54 -79 Helium 1 3 2 electron energy 2 1 3 3 tt 3 1 + 2 +

23 Multi-Photon Double Ionization Numerical Solution of the Schrödinger-Equation Parker & Taylor J. Phys. B34 (2001) h = 87 eV I = 2. 10 16 W/cm 2 momentum electron 1 [a.u.] momentum electron 2 [a.u.] Perturbation theory Colgan & Pindzola PRL 88 (2002) Two-Photon Absorption at h = 45 eV 1 h 2 h 3 h Absorption above threshold

24 Multi-photon single ionisation Two-photon innershell ionisation More Processes R. Hasbani, E. Cormier and H. Bachau J. Phys. B 33 (2000) 2101 S.A. Novikov and A.N. Hopersky J. Phys. B 33 (2000) 2287

25 Molecules Multi-Photon Processes in Atoms & Molecules Interactions with Molecular Ions Spectroscopy & Ionisation of Ions Atomic Physics

26 Molecules: Fixed-in-Space Shigemasa et al. PRL 74 (1995) Heiser & Becker et al. PRL 79 (1997) Landers & Dörner PRL 87 (2001) “Molecules illuminated from within” C O 10 eV Auger  

27 pump h 1 h 2 probe Fixed-in-Space & Pump-Probe photo-electron angular distribution fs time-scale for dissociation “Snapshots” of the time-evolution of intra-molecular potentials “Movie” of the dissociation reaction U. Becker, R. Dörner

28 Atomic Physics Multi-Photon Processes in Atoms & Molecules Interactions with Molecular Ions Spectroscopy & Ionisation of Ions

29 VUV Photodissociation of Molecular Ions A. Wolf, D. Zajfman, D. Schwalm Energy R DirectPredissociation Spontaneous radiative diss.

30 Hollow cathode ion source 5 kV electrostatic ion beam trap Einzel lens Kinetic energy release Angular distributions Cross sections Cold molecular ions Relaxation time (CH + ) ~ 0.4 sec VUV FEL Extracted ion bunch extraction time ~ 50 ns ~ 10 pulses per fill of trap Experimental Approach Photodissociation Imaging A. Wolf, D. Zajfman, D. Schwalm Molecular ions e.g. CH + Photon induced Dissociation

31 from Hartquist, Williams Cambridge Univ. Pr. 1995 H2H2 H2+H2+ CH + H3+H3+ CO HCO + e-e- C h e-e- H2H2 Interstellar cloud chemistry Example: CH + (production of oxygen-bearing molecules) CO

32 from Hartquist, Williams Cambridge Univ. Pr. 1995 H2H2 H2+H2+ CH + H3+H3+ CO HCO + e-e- C h e-e- H2H2 Interstellar cloud chemistry Example: CH + (production of oxygen-bearing molecules) loss mechanism photodissociation CO Ex: Diffuse Cloud ( ξ Ophiuchi): N Obser (CH + ) = 2.9·10 13 cm -2 N Model (CH + ) = 2.8·10 10 cm -2

33 estimated CH n + H2O+H2O+ H3O+H3O+ NH n + Relevant Photon Energies: Interstellar clouds: < 13.6 eV Close to stars: < 50 eV

34 estimated CH n + H2O+H2O+ H3O+H3O+ NH n + Relevant Photon Energies: Interstellar clouds: < 13.6 eV Close to stars: < 50 eV FEL -Radiation !!

35 Multi-Photon Processes in Atoms & Molecules Interactions with Molecular Ions Spectroscopy & Ionisation of Ions Atomic Physics (Approved TTF - Experiments)

36 1 m FEL-apparatus: (under construction) FEL beam    Experimental Approach J. Crespo, P. Baiersdorfer, J. Ullrich

37 Precision Spectroscopy on Ions I. Test of 1e - QED at Z  ~ 1 II. Few-Electron QED III. Determination of Nuclear Properties Magnetisation Distribution Magnetic Moment distribution Charge Radius Neutron Distribution IV. Electroweak Radiative Corrections V. Life Time Measurements FEL-Light:  /  

38 Lamb-shift in Li-like Ions QED contribution FEL bandwidth:  /  10 -4 Expected accuracy:   10 -6 BEVALAC (U 89+ ) 280.59  0.10 eV no data typical exp. accuracy:  E  E = 10 -3 -10 -5

39 urgently needed (opacity project) Photoionization of Ions very few data (luminosity) differential data (merged beams) M. A. Bautista J. Phys. B 33 (2000) L419 Photo ionization near threshold: Fe XV [2p 6 3s 2 ( 1 S)] R-matrix OP cross sections Multi-Photon Ionization! Above Threshold Ionization! Few photon – Few electrons! High Harmonic Generation Differential Data

40 Extracted Beams from the EBIT combine FEL-radiation Future: Exciting LEIF with FEL‘s

Download ppt "Atomic Physics with VUV-FEL Radiation R. Moshammer MPIK-Heidelberg SASE FEL Radiation (Self Amplification of Spontaneous Emission Free Electron Laser)"

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.
Program Degrad.1.0 Auger cascade model for electron thermalisation in gas mixtures produced by photons or particles in electric and magnetic fields S.F.Biagi.

Program Degrad.1.0 Auger cascade model for electron thermalisation in gas mixtures produced by photons or particles in electric and magnetic fields S.F.Biagi.
Interplay Between Electronic and Nuclear Motion in the Photodouble Ionization of H 2 T J Reddish, J Colgan, P Bolognesi, L Avaldi, M Gisselbrecht, M Lavollée,

Interplay Between Electronic and Nuclear Motion in the Photodouble Ionization of H 2 T J Reddish, J Colgan, P Bolognesi, L Avaldi, M Gisselbrecht, M Lavollée,
Soft X-ray light sources Light Sources Ulrike Frühling Bad Honnef 2014.

Soft X-ray light sources Light Sources Ulrike Frühling Bad Honnef 2014.
LCLS Atomic Physics with Intense X-rays at LCLS Philip H. Bucksbaum, University of Michigan, Ann Arbor, MI Roger Falcone, University of California, Berkeley,

LCLS Atomic Physics with Intense X-rays at LCLS Philip H. Bucksbaum, University of Michigan, Ann Arbor, MI Roger Falcone, University of California, Berkeley,
Imaginary time method and nonlinear ionization by powerful free electron lasers S.V. Popruzhenko Moscow Engineering Physics Institute, Moscow EMMI workshop.

Imaginary time method and nonlinear ionization by powerful free electron lasers S.V. Popruzhenko Moscow Engineering Physics Institute, Moscow EMMI workshop.
The Dynamics Of Molecules In Intense Ultrashort Laser Fields: Measurements of Ultrashort, Intense Laser-induced Fragmentation of The Simplest Molecular.

The Dynamics Of Molecules In Intense Ultrashort Laser Fields: Measurements of Ultrashort, Intense Laser-induced Fragmentation of The Simplest Molecular.
Intense Field Femtosecond Laser Interactions AMP TalkJune 2004 Ultrafast Laser Interactions with atoms, molecules, and ions Jarlath McKenna Supervisor:

Intense Field Femtosecond Laser Interactions AMP TalkJune 2004 Ultrafast Laser Interactions with atoms, molecules, and ions Jarlath McKenna Supervisor:
An STM Measures I(r) Tunneling is one of the simplest quantum mechanical process A Laser STM for Molecules Tunneling has transformed surface science. Scanning.

An STM Measures I(r) Tunneling is one of the simplest quantum mechanical process A Laser STM for Molecules Tunneling has transformed surface science. Scanning.
Generation of short pulses

Generation of short pulses
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.
Research Opportunities in Radiation-Induced Chemical Dynamics Scientific Opportunities for Studying Laser Excited Dynamics at the LCLS: David Bartels Notre.

Research Opportunities in Radiation-Induced Chemical Dynamics Scientific Opportunities for Studying Laser Excited Dynamics at the LCLS: David Bartels Notre.
FEL – opt. Laser cross-correlation Reinhard Kienberger 1,2,(3) 1 Institut für Photonik, Technische Universität Wien, Austria (Ferenc Krausz) 2 SPPS (April.

FEL – opt. Laser cross-correlation Reinhard Kienberger 1,2,(3) 1 Institut für Photonik, Technische Universität Wien, Austria (Ferenc Krausz) 2 SPPS (April.
Characterization of statistical properties of x-ray FEL radiation by means of few-photon processes Nina Rohringer and Robin Santra.

Characterization of statistical properties of x-ray FEL radiation by means of few-photon processes Nina Rohringer and Robin Santra.
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.
X-ray Free-Electron Lasers: Challenges for Theory, Cambridge, Massachusetts, USA, June 19, 2006 Infrared X-ray pump-probe spectroscopy Hans Ågren Department.

X-ray Free-Electron Lasers: Challenges for Theory, Cambridge, Massachusetts, USA, June 19, 2006 Infrared X-ray pump-probe spectroscopy Hans Ågren Department.
Laser-induced vibrational motion through impulsive ionization Grad students: Li Fang, Brad Moser Funding : NSF-AMO October 19, 2007 University of New Mexico.

Laser-induced vibrational motion through impulsive ionization Grad students: Li Fang, Brad Moser Funding : NSF-AMO October 19, 2007 University of New Mexico.
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.
EBIT – Electron Beam Ion Trap

EBIT – Electron Beam Ion Trap

Similar presentations

Ads by Google