Modeling of laser-driven proton radiography of dense matter

S. Kar; M. Borghesi; P. Audebert; A. Benuzzi-Mounaix; T. Boehly; D. Hicks; M. Koenig; K. Lancaster; S. Lepape; A. Mackinnon; P. Norreys; P. Patel; L. Romagnani

doi:10.1016/j.hedp.2007.11.002

Modeling of laser-driven proton radiography of dense matter

S. Kar
, M. Borghesi
, P. Audebert
, A. Benuzzi-Mounaix
, T. Boehly
, D. Hicks
, M. Koenig
, K. Lancaster
, S. Lepape
, A. Mackinnon
, P. Norreys
, P. Patel
, L. Romagnani

Queen's University of Belfast
University of Rochester Laboratory for Laser Energetics
Lawrence Livermore National Laboratory
CCLRC Rutherford Appleton Laboratory

Research output: Contribution to journal › Article › peer-review

Abstract

Laser-driven MeV proton beams are highly suitable for quantitative diagnosis of density profiles in dense matter by employing them as a particle probe in a point-projection imaging scheme. Via differential scattering and stopping, the technique allows to detect density modulations in dense compressed matter with intrinsic high spatial and temporal resolutions. The technique offers a viable alternative/complementary route to more established radiographic methods. A Monte-Carlo simulation package, MPRM, has been developed in order to quantify the density profile of the probed object from the experimentally obtained proton radiographs. A discussion of recent progress in this area is presented on the basis of analysis of experimental data, which has been supported by MPRM simulation.

Original language	English
Pages (from-to)	26-40
Number of pages	15
Journal	High Energy Density Physics
Volume	4
Issue number	1-2
DOIs	https://doi.org/10.1016/j.hedp.2007.11.002
Publication status	Published - 1 Apr 2008

Keywords

Inertial confinement fusion
Laser
Monte-Carlo
Proton
Radiography
Shock wave
Warm dense matter

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10.1016/j.hedp.2007.11.002

Cite this

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title = "Modeling of laser-driven proton radiography of dense matter",

abstract = "Laser-driven MeV proton beams are highly suitable for quantitative diagnosis of density profiles in dense matter by employing them as a particle probe in a point-projection imaging scheme. Via differential scattering and stopping, the technique allows to detect density modulations in dense compressed matter with intrinsic high spatial and temporal resolutions. The technique offers a viable alternative/complementary route to more established radiographic methods. A Monte-Carlo simulation package, MPRM, has been developed in order to quantify the density profile of the probed object from the experimentally obtained proton radiographs. A discussion of recent progress in this area is presented on the basis of analysis of experimental data, which has been supported by MPRM simulation.",

keywords = "Inertial confinement fusion, Laser, Monte-Carlo, Proton, Radiography, Shock wave, Warm dense matter",

author = "S. Kar and M. Borghesi and P. Audebert and A. Benuzzi-Mounaix and T. Boehly and D. Hicks and M. Koenig and K. Lancaster and S. Lepape and A. Mackinnon and P. Norreys and P. Patel and L. Romagnani",

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doi = "10.1016/j.hedp.2007.11.002",

language = "English",

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TY - JOUR

T1 - Modeling of laser-driven proton radiography of dense matter

AU - Kar, S.

AU - Borghesi, M.

AU - Audebert, P.

AU - Benuzzi-Mounaix, A.

AU - Boehly, T.

AU - Hicks, D.

AU - Koenig, M.

AU - Lancaster, K.

AU - Lepape, S.

AU - Mackinnon, A.

AU - Norreys, P.

AU - Patel, P.

AU - Romagnani, L.

PY - 2008/4/1

Y1 - 2008/4/1

N2 - Laser-driven MeV proton beams are highly suitable for quantitative diagnosis of density profiles in dense matter by employing them as a particle probe in a point-projection imaging scheme. Via differential scattering and stopping, the technique allows to detect density modulations in dense compressed matter with intrinsic high spatial and temporal resolutions. The technique offers a viable alternative/complementary route to more established radiographic methods. A Monte-Carlo simulation package, MPRM, has been developed in order to quantify the density profile of the probed object from the experimentally obtained proton radiographs. A discussion of recent progress in this area is presented on the basis of analysis of experimental data, which has been supported by MPRM simulation.

AB - Laser-driven MeV proton beams are highly suitable for quantitative diagnosis of density profiles in dense matter by employing them as a particle probe in a point-projection imaging scheme. Via differential scattering and stopping, the technique allows to detect density modulations in dense compressed matter with intrinsic high spatial and temporal resolutions. The technique offers a viable alternative/complementary route to more established radiographic methods. A Monte-Carlo simulation package, MPRM, has been developed in order to quantify the density profile of the probed object from the experimentally obtained proton radiographs. A discussion of recent progress in this area is presented on the basis of analysis of experimental data, which has been supported by MPRM simulation.

KW - Inertial confinement fusion

KW - Laser

KW - Monte-Carlo

KW - Proton

KW - Radiography

KW - Shock wave

KW - Warm dense matter

U2 - 10.1016/j.hedp.2007.11.002

DO - 10.1016/j.hedp.2007.11.002

M3 - Article

AN - SCOPUS:40949122689

SN - 1574-1818

VL - 4

SP - 26

EP - 40

JO - High Energy Density Physics

JF - High Energy Density Physics

IS - 1-2

ER -

Modeling of laser-driven proton radiography of dense matter

Abstract

Keywords

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