Direct Experimental Evidence of Back-Surface Ion Acceleration from Laser-Irradiated Gold Foils | Zendy

Matthew Allen | Zendy; P. K. Patel | Zendy; A. J. Mackin | Zendy; D. Price | Zendy; S. C. Wilks | Zendy; Edward Morse | Zendy

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Direct Experimental Evidence of Back-Surface Ion Acceleration from Laser-Irradiated Gold Foils

Author(s) -

Matthew Allen,

P. K. Patel,

A. J. Mackin,

D. Price,

S. C. Wilks,

Edward Morse

Publication year - 2004

Publication title -

physical review letters

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 3.688

H-Index - 673

eISSN - 1079-7114

pISSN - 0031-9007

DOI - 10.1103/physrevlett.93.265004

Subject(s) - irradiation , proton , ion , yield (engineering) , materials science , laser , atomic physics , sputtering , acceleration , beam (structure) , particle (ecology) , optics , nuclear physics , physics , nanotechnology , thin film , composite material , oceanography , quantum mechanics , geology , classical mechanics

Au foils were irradiated with a 100-TW, 100-fs laser at intensities greater than 10(20) W/cm2 producing proton beams with a total yield of approximately 10(11) and maximum proton energy of >9 MeV. Removing contamination from the back surface of Au foils with an Ar-ion sputter gun reduced the total yield of accelerated protons to less than 1% of the yield observed without removing contamination. Removing contamination from the front surface (laser-interaction side) of the target had no observable effect on the proton beam. We present a one-dimensional particle-in-cell simulation that models the experiment. Both experimental and simulation results are consistent with the back-surface acceleration mechanism described in the text.

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