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AWAKE Experiment: Proton Driven Wake Field Acceleration at Wigner Research Center

This paper discusses the AWAKE experiment at Wigner Research Center, focusing on the contribution of using short chirped laser pulses to enhance the single-ionization cross sections and create a homogeneous plasma. It also presents theoretical contributions and additional accelerator-related activities in Hungary.

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AWAKE Experiment: Proton Driven Wake Field Acceleration at Wigner Research Center

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  1. Accelerator R& D or The contribution of the Wigner Research Center to the Proton Driven Wake Field Accelaration (AWAKE) Experiment 4 October 2013, Budapest Imre F. Barna

  2. Outline - Introduction of the problem - One possible solution - the AWAKE experiment - Our contribution experimental and theoretical

  3. The field of interest Recent accelerator technology (accelarating in vacuum with radio frequency) like CERN reached its physical, geometrical limits CERN is 27 km long, the accelarating gradient is 50 MV/m What is the way out? Vacuum plasma Radio frequency quick charged particle/short laser pulse

  4. The idea of the AWAKE Experiment (Fig. Is taken from Patric Muggli)

  5. Our contribution to improve the AWAKE Experiment Idea: use a short chirped laser pulse to populate the 7s and 5d two-photon resonant excited states to enhance the total single-ionization cross sections in the GeV proton – Rb collisions and create a homogeneous plasma (Model: with a laser-atom calculation coupled to ion-atom collision including propagation phenomena) Rubidium-85 energy levels

  6. The experimental setup Rb dispenser MCP detector The vacuum chamber The Rb atom beam distribution

  7. The laser system Primary laser source - fs-duration system: Ti:sapphire oscillator + regenerative amp. the laboratory is used for HHG experiments, surface plasmons Clean room: 3000-4000 particles / foot^3

  8. Output parameters of the laser system Typical values 806 nm 4.1W 9 mm (1/e2 ,Gauss) Linear, vertical 1 kHz 35 fs 0.25% 800nm 30nm Parameters Mean wavelength Average Power Beam Diameter: Polarisation: Repetition Rate Pulse duration (FWHM): Energy. stab. rms (%): Medium wavelength: Bandwidth (FWHM):

  9. Our theoretical contributions The group has experience on manipulating atomic transitions with chirped laser pulses.Dynamics of the populations for positive and negative frequency chirp 0 I5> I2> I3> I4> I1> I0> GP. Djotyan, JS. Bakos, G. Demeter, PN. Ignacz, MA. Kedves, Zs. Sorlei, J. Szigeti, Z.Toth, Phys.Rev A, 68, 053409 (2003)

  10. Proton - Rb collision - there are some scaling laws available for single ionization in ion- atom collision but only from the ground state from my Phd http://geb.uni-giessen.de/geb/volltexte/2003/1036/pdf/BarnaImre-2002-07-03.pdf or I.F Barna, N. Grün, W. Scheid, Eur. Phys. J.D. 25, 239 (2002) from my colleague: C. Pfeiffer, N. Grün, W. Scheid, J. Phys. B: At. Mol. Opt. Phys. 79, 3621 (1997)

  11. Proton - Rb collision -In ion-atom collision the semiclassical approx. is used the projectile is treated classicaly and flies on a straight line - the Knudsen parameter describes the external field if Zproj/vproj < 0.1 perturbative regime, our case 1st Born approx is valid matrix element: transition amplitude: Total ionization cross section: Work is in progress - there are some scaling laws for single ionization in ion-atom collision but from the ground state

  12. Additional ideas, activity Prof. Varró has analytic solutions for particles in underdense plasma in Dirac/KG Eq.Mr. Pocsai Msc. Student studies the classical motion of charged particles in underdense plasma

  13. Publications Conference proceedings: First European Advanced Accelerator Concepts Workshop or on the Preprint Server: http://arxiv.org/abs/1309.2442

  14. Additional accelerator coupled activities in Hungary/Wigner In the planned ELI - ALPS superlaser at Szeged we plan to accelerate electrons and protons with short laser pulses accelerated protons will be used for hadron therapy

  15. Thank you for your attention!

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