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ENHANCED LASER-DRIVEN PROTON ACCELERATION IN MASS-LIMITED TARGETS

ENHANCED LASER-DRIVEN PROTON ACCELERATION IN MASS-LIMITED TARGETS. J an Psikal. PhD student at. 1 Department of Physical Electronics, Faculty of Nuclear Sciences and Physical Engineering, Czech Technical University in Prague

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ENHANCED LASER-DRIVEN PROTON ACCELERATION IN MASS-LIMITED TARGETS

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  1. ENHANCED LASER-DRIVEN PROTON ACCELERATION IN MASS-LIMITED TARGETS Jan Psikal PhD student at 1Department of Physical Electronics, Faculty of Nuclear Sciences and Physical Engineering, Czech Technical University in Prague 2 Centre Lasers Intenses et Applications, CNRS – CEA – Universite Bordeaux 1, Talence, France 7th DDFI workshop, Prague 3.5. – 6.5.2009

  2. in collaboration with … Faculty of Nuclear Sciences and Physical Engineering, CTU Prague, Czechia J. Limpouch, O. Klimo CELIA, Universite Bordeaux 1 - CNRS – CEA, Talence, France V. Tikhonchuk, E. D’Humieres Department of Physics andAstronomy, The Queen’s University of Belfast, UK S. Ter-Avetisyan, S. Kar LULI, Ecole Polytechnique – CNRS – CEA - UPMC,Palaiseau, France J. Fuchs and others Vavilov State Optical Institute, St. Petersburg, Russia A. Andreev

  3. Laser-driven proton acceleration Target normal sheath acceleration (TNSA) mechanism 1) electron heating by a short and intense laser pulse two temperature electron distribution – cold and hot electrons 2) electric fields1012-1013 V/m (104 timeshigher than in conventional accelerators) 3) ion acceleration hot electrons are cooled down and protons originated from water or hydrocarbon surface contaminants are accelerated

  4. Possible applications and their requirements - proton radiography of laser interactions (already used) - oncological hadrontherapy and medical physics - neutron source and isotope production - fast ignition of inertial confinement fusion applications employing laser-driven proton beams requires improvement of the beam parameters in several areas: 1) increase of maximum energy 2) increase of laser-to-proton conversion efficiency 3) reduction of the beam divergence 4) reduction of the ion energy spread (i.e., monoenergetic beams)

  5. Electron recirculation in thin foils Y. Sentoku et al., Phys. Plasmas 10, 2009 (2003) A. J. Mackinnon et al., Phys. Rev. Lett. 88, 215006 (2002) decreasing foil thickness  increasing hot electron density (due to recirculation and lower transverse electron beam spread)  higher accelerating electric fields  higher ion acceleration efficiency (maximum and total proton energies)

  6. Electron recirculation in mass-limited foils Lp > Ds Lp spatial length of laser pulse Ds transverse size of foil

  7. Experiments with limited mass foils laser pulse of duration 350 fs, =529 nm, I21019Wcm-2 m2, beam width FWHM = 6 m is incident (incidence angle 45º) on a thin Au foil (thickness 2 m) with reduced target transverse surface area down to 50  80 m2 S. Buffenchouxet al., Phys. Rev. Lett., submitted

  8. Experiments with limited mass foils with decreasing target surface (and constant foil thickness) • enhancement of maximum proton energy • strong enhancement of laser-to-proton conversion efficiency • reduced ion beam divergence S. Buffenchouxet al., Phys. Rev. Lett., submitted • azimuthally averaged angular protondose profiles, extracted from films corresponding to E/Emax~0. • FWHM of angular transverse proton beam profiles

  9. 2D3V PIC simulations Simulation parameters: To decrease high computational demands, the laser pulse duration and foil surface (e.g. transverse foil size in 2D case) are reduced in our simulations. Nevertheless, the ratio of the transverse foil size to the spatial length of the pulse is similar (approx. 0.6 for smaller foil – 5080 m2 in the experiment - and 2.4 for larger foil - 200300 m2 in the experiment). laser pulse duration 40 (=2 fs) is incident on target from 35 to 75, intensity I=3.41019 W/cm2, beam width(FWHM)7, =600 nm, target density 20nc composed of protons and electrons 1) smaller foil 202 L<Ds/vetrans 2) larger foil 802 L>Ds/vetrans vetrans  c Ds transverse foil size, vetrans transverse velocity of hot electrons

  10. Time evolution of electron energy spectra – smaller foil

  11. Time evolution of electron energy spectra – larger foil

  12. Proton energy spectra characteristics maximum proton energies are in agreement with experiment higher accelerating electric field is sustained for a longer time as hot electrons are reflected back from foil edges proton conversion efficiency – difficult to determine from numerical simulations (which protons to take into account?) protons emitted from the central part of the foil – 3.5% for larger vs.5.5% for smaller foil – which is the difference 60% (but at least 400% in experiment!)

  13. How to explain the discrepancy in the conversion efficiency? maximum proton energy P. Mora, Phys. Rev. Lett. 90, 185002 (2003) J. Schreiber et al., Phys. Rev. Lett. 97, 045005 (2006) total energy (e.g., conversion efficiency) conversion efficiency is overestimated in 2D, we expect higher difference in hot electron density 3D approach is necessary

  14. Mutual interaction of two ion species proton phase space proton energy spectra • Athin layerof protons at the rear surface of thetarget is accelerated by a strong electricfield. Heavy ionsare accelereted somewhat later because of their inertia. They shield the sheathelectric field for other protons from deeper layers and also interact with earlieraccelerated protons. • The fastest protons are futher accelerated by electrons,the slower (close to heavy ion front) are accelerated by heavy ion front which acts like a piston and are decelerated by Coulomb explosion of the fastest protons at the same time.

  15. Mutual interaction of two ion species Simulation parameters: laser pulse is incident perpendicularly on foils, plasma composed of protons and C4+ ionsin ratio 1:1 1) smaller foil 202 2) larger foil 802 quasimonoenergetic feature in proton energy spectra is observed for smaller foil Z1=4, Z2=1, A1=12, A2=1   1.6 MeV V. T. Tikhonchuk et al. Plasma Phys. Control. Fusion 47, B869 (2005)

  16. Why we do not observe this modulation in proton energy spectra for larger foil? smaller surface larger surface overall energy spectra:

  17. Experimental results parameters: perpendicular incidence, pulse duration 5 ps, focal spot 4 m, intensity 31020 Wcm-2 S. Kar, private communication

  18. Conclusions • reduced transverse sizes of a thin foil lead to hot electron recirculation from foil edges, which enhances laser-to-proton conversion efficiency and maximum proton energy • to observe appropriate scaling of the conversion efficiency, 3D simulations have to be used • strong modulations in proton energy spectra (dips and peaks) could be observed in foils with transverse sizes of about several times of the laser focal spot size

  19. Thank you for your attention

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