Author:
BORGHESI M.,CAMPBELL D.H.,SCHIAVI A.,WILLI O.,MACKINNON A.J.,HICKS D.,PATEL P.,GIZZI L.A.,GALIMBERTI M.,CLARKE R.J.
Abstract
One of the most exciting results recently obtained in the
ultraintense interaction research area is the observation of
beams of protons with energies up to several tens of megaelectron
volts, generated during the interaction of ultraintense picosecond
pulses with solid targets. The particular properties of these
beams (high brilliance, small source size, high degree of
collimation, short duration) make them of exceptional interest
in view of diagnostic applications. In a series of experiments
carried out at the Rutherford Appleton Laboratory (RAL) and
at the Lawrence Livermore National Laboratory (LLNL), the
laser-produced proton beams have been characterized in view
of their application as a particle probe for high-density matter,
and applied to diagnose ultraintense laser–plasma
interactions. In general, the intensity cross section of a proton
beam traversing matter will be modified both by collisional
stopping/scattering, and deflections caused by electric/magnetic
fields. With a suitable choice of irradiation geometry and target
parameters, the proton probe can be made mainly sensitive to
the electric field distribution in the object probed. Therefore,
point projection proton imaging appears as a powerful and unique
technique for electric field detection in laser-irradiated targets
and plasmas. The first measurements of transient electric fields
in high-intensity laser-plasma interactions have been obtained
with this technique.
Subject
Electrical and Electronic Engineering,Condensed Matter Physics,Atomic and Molecular Physics, and Optics
Cited by
51 articles.
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