Self-modulation and anomalous collective scattering of laser produced intense ion beam in plasmas

K. Mima; J. Fuchs; T. Taguchi; J. Alvarez; J. R. Marquès; S. N. Chen; T. Tajima; J. M. Perlado

doi:10.1016/j.mre.2017.12.004

Self-modulation and anomalous collective scattering of laser produced intense ion beam in plasmas

K. Mima
, J. Fuchs
, T. Taguchi
, J. Alvarez
, J. R. Marquès
, S. N. Chen
, T. Tajima
, J. M. Perlado

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

Abstract

The collective interaction between intense ion beams and plasmas is studied by simulations and experiments, where an intense proton beam produced by a short pulse laser is injected into a pre-ionized gas. It is found that, depending on its current density, collective effects can significantly alter the propagated ion beam and the stopping power. The quantitative agreement that is found between theories and experiments constitutes the first validation of the collective interaction theory. The effects in the interaction between intense ion beams and background gas plasmas are of importance for the design of laser fusion reactors as well as for beam physics.

Original language	English
Pages (from-to)	127-134
Number of pages	8
Journal	Matter and Radiation at Extremes
Volume	3
Issue number	3
DOIs	https://doi.org/10.1016/j.mre.2017.12.004
Publication status	Published - 1 May 2018
Externally published	Yes

Keywords

Electron plasma wave
Laser plasma interaction
Proton beam
Two stream instabilities
Ultra intense short pulse laser
Wake field

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10.1016/j.mre.2017.12.004

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title = "Self-modulation and anomalous collective scattering of laser produced intense ion beam in plasmas",

abstract = "The collective interaction between intense ion beams and plasmas is studied by simulations and experiments, where an intense proton beam produced by a short pulse laser is injected into a pre-ionized gas. It is found that, depending on its current density, collective effects can significantly alter the propagated ion beam and the stopping power. The quantitative agreement that is found between theories and experiments constitutes the first validation of the collective interaction theory. The effects in the interaction between intense ion beams and background gas plasmas are of importance for the design of laser fusion reactors as well as for beam physics.",

keywords = "Electron plasma wave, Laser plasma interaction, Proton beam, Two stream instabilities, Ultra intense short pulse laser, Wake field",

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doi = "10.1016/j.mre.2017.12.004",

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T1 - Self-modulation and anomalous collective scattering of laser produced intense ion beam in plasmas

AU - Mima, K.

AU - Fuchs, J.

AU - Taguchi, T.

AU - Alvarez, J.

AU - Marquès, J. R.

AU - Chen, S. N.

AU - Tajima, T.

AU - Perlado, J. M.

PY - 2018/5/1

Y1 - 2018/5/1

N2 - The collective interaction between intense ion beams and plasmas is studied by simulations and experiments, where an intense proton beam produced by a short pulse laser is injected into a pre-ionized gas. It is found that, depending on its current density, collective effects can significantly alter the propagated ion beam and the stopping power. The quantitative agreement that is found between theories and experiments constitutes the first validation of the collective interaction theory. The effects in the interaction between intense ion beams and background gas plasmas are of importance for the design of laser fusion reactors as well as for beam physics.

AB - The collective interaction between intense ion beams and plasmas is studied by simulations and experiments, where an intense proton beam produced by a short pulse laser is injected into a pre-ionized gas. It is found that, depending on its current density, collective effects can significantly alter the propagated ion beam and the stopping power. The quantitative agreement that is found between theories and experiments constitutes the first validation of the collective interaction theory. The effects in the interaction between intense ion beams and background gas plasmas are of importance for the design of laser fusion reactors as well as for beam physics.

KW - Electron plasma wave

KW - Laser plasma interaction

KW - Proton beam

KW - Two stream instabilities

KW - Ultra intense short pulse laser

KW - Wake field

U2 - 10.1016/j.mre.2017.12.004

DO - 10.1016/j.mre.2017.12.004

M3 - Article

AN - SCOPUS:85047849118

SN - 2468-2047

VL - 3

SP - 127

EP - 134

JO - Matter and Radiation at Extremes

JF - Matter and Radiation at Extremes

IS - 3

ER -

Self-modulation and anomalous collective scattering of laser produced intense ion beam in plasmas

Abstract

Keywords

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