applications and prognosis of coherent soft xapplications ... · lecture 12 applications and...
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Lecture 12Applications and prognosis of coherent soft xApplications and prognosis of coherent soft x-
ray lasers. Feasibility of γ-ray lasers
OutlineApplications of x ray lasers based on the so called “water windows” Soft x ray• Applications of x-ray lasers based on the so-called water windows . Soft x-raymicroscopy of biological objects. Soft x-ray reflective microscopy using a Fresnellens requires an x-ray laser. Experimental setup of soft x-ray laser holographymade by an x-ray Ne-like (Se XXV) laser.y y ( )
• Experimental setup of soft x-ray laser interferometry. Mach-Zehnderinterferometer using two x-ray gratings for x-ray interferometry. X-rayinterferometry of dense plasma.
• Experimental setup of face-on soft x-ray laser radiography. Experimental setup ofx-ray laser Thomson scattering.
• Patterning by Ar+8-laser. Lithography and ablation by Ar+8-laser (46.9 nm)• Probing hierarchies in space and time of x-ray applications.• The decrease of wavelengths of x-ray lasers would increase their applications. γ-
ray lasers?
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Outline ctd.Outline ctd.
• Anti-Stokes γ-ray laser.C t tt i• Compton scattering γ-ray sources.
• Concept of annihilation-based γ-ray laser.• Understanding γ-ray lasers requires theory, computations and
experimentsexperiments.• Perspectives in X-ray quantum optics.• Understanding x-ray quantum optics requires theory,
computations and experimentscomputations and experiments• Problems as home assignments• References
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Many applications of x-ray lasers are based on the so-called water windowsthe so-called water windows
Fig. 1 Penetration distances in water and protein for electrons and X-rays. The edges of “water windows” are marked by two vertical red dashed lines (from Soft X-ray Microscopes and Their Biological Applications Q Rev
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marked by two vertical red dashed lines (from Soft X ray Microscopes and Their Biological Applications, Q. Rev. Biophys., 28, 33 (1995)).
Soft x-ray microscopy of biological objects
Elliptic mirrorTarget
1kJ CO2 laser
90 kG magnetX-ray laser beam
Spectrometer axial direction)
90 kG magnet
Spectrometer (transverse direction) Microscope(transverse direction) Microscope
Fig 2 Schema of soft x-ray microscopy of biological objects The
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Fig. 2 Schema of soft x ray microscopy of biological objects. The PMMA photo of a HeLa biocell (from Science 247, 1553(1990)).
Soft x-ray reflective microscopy using a Fresnel lens requires an x ray lasera Fresnel lens requires an x-ray laser
CCD camera 46.9 nm laser (a)
Fresnel lens
Target (Si crystal)
Schwarzschildcollimator
(b)
Fig. 3 Schema of the soft x-ray reflective microscopy. Photo of the fringes on the surface of the Si crystal (a) 250 nm (b) 100 nm (from US Patent5 177 774 (J 5 1993))
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5,177,774 (Jan.5, 1993)).
Experimental setup of soft x-ray laser holography made by an x ray Ne like (Se XXV) lasermade by an x-ray Ne-like (Se XXV) laser
Film detector
Target Multilayer x-ray mirrorTarget
20nm x-ray Ne-like (Se XXV) lasery ( )
Fig. 4 Schema of the first x-ray laser holography made by using an x-ray Ne-like (Se XXV) laser (from Science 238, 517 (1987)).
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Experimental setup of soft x-ray laser interferometryinterferometry
Fig 5 Experimental setup of soft x-ray laser interferometry (from
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Fig. 5 Experimental setup of soft x ray laser interferometry (from Physical Review Letters, 74, 3991 (1995)).
Mach-Zehnder interferometer using two x ray gratings for x ray interferometryx-ray gratings for x-ray interferometry
Nd-YaG laser
X-ray laserMirror 2
Focusing Objective Mirror
1 i 2nd grating1st grating 2nd gratingMirror 1 2.7mm
Fig 6 Mach-Zehnder interferometer using two x-ray gratings for x-ray
MCP-CCD detector
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Fig. 6 Mach Zehnder interferometer using two x ray gratings for x ray interferometry (from Opt. Lett. 25, 356 (2000)).
X-ray interferometry of dense plasma
ty (c
m-3
)on
den
sit
Ele
ctro
Distance (μm)
Fig. 7 The scanning soft X-ray microscope requires spatially coherent radiation. (a) Interferogram 0;5 ns time moment after 600 ps pick, 0;4 JLIP. (b) Electron density near the target surface vs the distance from the target (from Phys. Rev. Lett. 89, 065004 (2002)).
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Experimental setup of face-on soft x-ray l di hlaser radiography
Fig 8 E i t l t f f ft l di h (f
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Fig. 8 Experimental setup of face-on soft x-ray laser radiography (from Physical Review Letters, 76, 3574 (1996)).
Experimental setup of x-ray laser Thomson tt iscattering
Fig 9 E i t l t f l Th tt i (f
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Fig. 9 Experimental setup of x-ray laser Thomson scattering (from Central Laser Facility Annual Report 2001/2002, 45 (2002)).
Patterning by Ar+8-laserSample
X laserLloyd mirror
X-laser
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Fig. 10 Patterning by Ar+8-laser (from L’Aquila U., Italy).
Lithography and ablation by Ar+8-laser (46.9 nm)
Lithography on PMM resist
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Fig. 11 Lithography on PMM resists and ablation of SiO2 by Ar+8-
laser (from U. of L’Aquila, Italy)
Probing in space and time. Perspectives (A)X-rayX ray
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Fig. 12 Probing hierarchies in space and time (from www.coe. berkeley.edu).
Probing in space and time. Perspectives (B)
TÁMOP-4.1.1.C-12/1/KONV-2012-0005 project 15Fig.13 Probing hierarchies in space and time (B) (from www.coe. berkeley.edu).
Decrease of wavelengths of x-ray lasers would increase their applications γ ray laserswould increase their applications γ-ray lasers
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From [2]
Anti-Stokes γ-ray laser
Fig. 14 Schematic diagram for the ti St k t iti (f [3])anti-Stokes transition (from [3]).
Fig. 15 Decay diagram for 179Hf (from [3]).
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g y g ( [ ])
Compton scattering γ-ray sources (A)
From [4]:From [4]:
Fig. 16
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Compton scattering γ-ray sources (B)
Fig. 17 (from [4])
Fig. 18
(from [4])
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Concept of annihilation-based γ-ray laser
Fi 19Fig. 19 Annihilation γ-laser concept. Positrons from a storage device are suddenly deposited in a tube several centimeters long and a few microns in diameter. The positrons form triplet positronium atoms that quickly cool to a few thousand degrees C and form a Bose-Einstein condensate. A microwave burst converts the positronium to the singlet state and a spontaneous annihilation photon that happens to propagate along the tube is amplified via stimulated
i i t f f l h t b f ihil ti h t (f [5])
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emission to form a powerful coherent beam of annihilation photons (from [5])
Understanding γ-ray lasers requires theory, t ti d i tcomputations and experiments
Theory Computations
Experiment
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Fig. 20 Understanding γ-ray lasers requires theory, computations and experiments
Perspectives in x-ray quantum opticsLet me show the perspective topics related to x-ray quantum optics, which were recently discussed in Ref. [6]
1. Individual photons and photons correlations 1.1. Hunbary Brown-Twiss effect and ghost imaging.1.2 Parametric down conversion (PDC). Possible applications of X-ray PDS.
Let me show the perspective topics related to x ray quantum optics, which were recently discussed in Ref. [6]
1.3 Single-photon superradiance1.4 Collective Lamb shift1.5 Coherent control of nuclear forward scattering1.6 Generation of entangled X-ray photons2. Strong coupling X-ray quantum optics2.1 Coherent γ-ray radiation via electromagnetically induced transparency for nuclear transitions2.2. Electromagnetically induced transparency via cooperative emission in a cavity that contains resonant nuclei2.3 Control of the cooperative branching ratio of a given nuclear state2.4 X-ray FEL-based nuclear quantum optics2.5 Stimulated-Raman-adiabatic-passage (STIRAP) for transfer of population between long-lived states of nuclear isomers3. Intense-field X-ray quantum optics3.1 Resonance fluorescence3.2 Laser-dressed Auger decay3.3 High-order harmonic generation manipulated by XUV/X-ray light3.4 X-ray absorption by laser-dressed atoms3.5 Parametric γ-generation
For details, see B.W. Adams et al., Review X-ray quantum optics, J. Modern Opt. 60: 11-20 (2013)
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Understanding x-ray quantum optics requires th t ti d i ttheory, computations and experiments
Theory Computations
Experiment
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Fig. 21 Understanding x-ray quantum οπτιχσ requires theory, computations and experiments
Problems as home assignments (A)1. Describe the advantages of the applications of x-ray lasers for the interferometric
testing of soft x-ray multi-layer optics.2. Describe the advantages of the applications of x-ray lasers for testing of patterned2. Describe the advantages of the applications of x ray lasers for testing of patterned
polymer photoresists. Consider the reflective mask for soft x-ray lithography.3. Point out the advantages of the applications of the capillary Z-pinch Ar+8-laser (U.
of L’Aquila, Italy) for lithography on PMM resists and ablation of solids.4. Explain the use of coherent soft X-ray scattering for the soft x-ray hologramp a e use o co e e so ay sca e g o e so ay o og a
(analyze the experimental hologram obtained at the wavelength 1.59 nm).5. Explain why a scanning soft x-ray microscope requires spatially coherent
radiation.6. Why would the decrease of wavelengths of soft x-ray lasers increase theiry g y
applications?7. Describe soft x-ray microscopy and cryo x-ray tomography.1. Describe the tomographic reconstruction in soft x-ray spectral region. Give
examples of X-tomography of Saccharomeyces cerevisiae and a Yeast cell as thep g p y ybio-nanotomography for 3D imaging of cells.
8. How can magnetic domains be imaged at different x-ray photon energies?9. Why is the imaging of ultrafast spin dynamics possible with magnetic soft x-ray
microscopy?py
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Problems as home assignments (B)
11. Why are x-ray lasers suitable for the analysis of advanced IC devices by x-rays?y y y y y16. Describe probing hierarchies in space and time.17. Compare briefly x-ray scattering, resonant x-ray scattering and dynamic x-ray scattering.18. Describe features of coherent soft-x-ray scattering.19. Consider the static coherent soft X-ray “Speckle metrology” of thin film ferromagnets.y p gy g20. Explain the relation: Coherence of soft x-rays correlations complexity.21. Explain the statement: The decrease of the wavelengths of x-ray lasers would increase their
applications γ-ray lasers.22. Explain the physical principle of Anti-Stokes γ-ray laser.γ23. Explain Compton scattering γ-ray sources (lasers).24. Give a concept of the annihilation-based γ-ray laser.25. Why does understanding γ-ray lasers require theory, computations and experiments?26. Give examples of x-ray quantum optics and its connection with x-ray lasers.
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References1. David Attwood, Soft-X-rays and Extreme Ultraviolet Radiation, Cambridge University
Press, 2000; David Attwood, Soft-X-rays and Extreme Ultraviolet Radiation (www.coe. berkeley.edu).
2. F.J. Agee, Review of induced gamma emission and gamma-ray laser research, Hyperfine interactions 143, 1 (2002).
3. S. Eliezer, J.M. Martitez-Val, and J.L. Borowitz, On the possibility for a gamma-ray laser, Laser Physics %, 323 (1995)
4. M. Shverdin, F. Albert, D. Gibson, M. Messerly, F. Hartemann, C. Siders, C. Barty, (LLNL, USA), Laser technology for compact, narrow-bandwidth gamma-ray sources, (www.intechopen.com)
5. A.P. Mills, Jr., Positronium annihilation gamma ray laser, AFRL-RW-EG-TR-2009-7080, Final report. Air force research laboratory, munitions directorate (USA)
6. B.W. Adams et al., Review X-ray quantum optics, J. Modern Opt. 60: 11-20 (2013)7. Application of soft x-ray lasers, S Hatae* and G J Tallents, Univ. of York, UK.
For additional information see: 1. R. C. Elton, X-ray lasers, Academic Press, 1990.2. David Attwood, Soft-X-rays and Extreme Ultraviolet Radiation, Cambridge University
Press, 2000; David Attwood, Soft-X-rays and Extreme Ultraviolet Radiation (www.coe. berkeley.edu).
3. J.J. Rocca, Review article. Table-top soft x-ray lasers, Rev. Sci. Instr. 70, 3799 (1999)f f4. H. Daido, Review of soft x-ray laser researches and developments, Rep. Prog. Phys.
65, 1513 (2002) 5. A.V. Vinogradov, J.J. Rocca, Repetitively pulsed X-ray laser operating on the 3p-3s
transition of the Ne-like argon in a capillary discharge, Kvant. Electron., 33, 7 (2003)6 S S k P J l X R l t t d f t L Ph L tt 6
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6. S. Suckewer, P. Jaegle, X-Ray laser: past, present, and future, Laser Phys. Lett. 6, 411 (2009).