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On intense proton beam generation and transport in hollow cones
Author(s) -
J. J. Honrubia,
A. Morace,
M. Murakami
Publication year - 2016
Publication title -
matter and radiation at extremes
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.006
H-Index - 18
eISSN - 2468-2047
pISSN - 2468-080X
DOI - 10.1016/j.mre.2016.11.001
Subject(s) - proton , foil method , beam (structure) , magnetic field , atomic physics , acceleration , hydrogen , electron , laser , plasma , optics , beam divergence , physics , materials science , beam diameter , laser beams , nuclear physics , classical mechanics , composite material , quantum mechanics
Proton generation, transport and interaction with hollow cone targets are investigated by means of two-dimensional PIC simulations. A scaled-down hollow cone with gold walls, a carbon tip and a curved hydrogen foil inside the cone has been considered. Proton acceleration is driven by a 1020 W·cm−2 and 1 ps laser pulse focused on the hydrogen foil. Simulations show an important surface current at the cone walls which generates a magnetic field. This magnetic field is dragged by the quasi-neutral plasma formed by fast protons and co-moving electrons when they propagate towards the cone tip. As a result, a tens of kT Bz field is set up at the cone tip, which is strong enough to deflect the protons and increase the beam divergence substantially. We propose using heavy materials at the cone tip and increasing the laser intensity in order to mitigate magnetic field generation and proton beam divergence

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