Physics and phenomenology ofweakly magnetized, relativistic astrophysical shock waves

Arno Vanthieghem; Martin Lemoine; Illya Plotnikov; Anna Grassi; Mickael Grech; Laurent Gremillet; Guy Pelletier

doi:10.3390/GALAXIES8020033

Physics and phenomenology ofweakly magnetized, relativistic astrophysical shock waves

Arno Vanthieghem
, Martin Lemoine
, Illya Plotnikov
, Anna Grassi
, Mickael Grech
, Laurent Gremillet
, Guy Pelletier

Research output: Contribution to journal › Review article › peer-review

Abstract

Weakly magnetized, relativistic collisionless shock waves are not only the natural offsprings of relativistic jets in high-energy astrophysical sources, they are also associated with some of the most outstanding displays of energy dissipation through particle acceleration and radiation. Perhaps their most peculiar and exciting feature is that the magnetized turbulence that sustains the acceleration process, and (possibly) the secondary radiation itself, is self-excited by the accelerated particles themselves, so that the phenomenology of these shock waves hinges strongly on the microphysics of the shock. In this review, we draw a status report of this microphysics, benchmarking analytical arguments with particle-in-cell simulations, and extract consequences of direct interest to the phenomenology, regarding, in particular, the so-called microphysical parameters used in phenomenological studies.

Original language	English
Article number	33
Journal	Galaxies
Volume	8
Issue number	2
DOIs	https://doi.org/10.3390/GALAXIES8020033
Publication status	Published - 1 Jun 2020

Keywords

Collisionless shock in plasma
Cosmic ray acceleration
Plasma microinstabilities
Shock waves and discontinuities

Access to Document

10.3390/GALAXIES8020033

Cite this

@article{137c2be9fd1544388d5d8cd7fb182b28,

title = "Physics and phenomenology ofweakly magnetized, relativistic astrophysical shock waves",

abstract = "Weakly magnetized, relativistic collisionless shock waves are not only the natural offsprings of relativistic jets in high-energy astrophysical sources, they are also associated with some of the most outstanding displays of energy dissipation through particle acceleration and radiation. Perhaps their most peculiar and exciting feature is that the magnetized turbulence that sustains the acceleration process, and (possibly) the secondary radiation itself, is self-excited by the accelerated particles themselves, so that the phenomenology of these shock waves hinges strongly on the microphysics of the shock. In this review, we draw a status report of this microphysics, benchmarking analytical arguments with particle-in-cell simulations, and extract consequences of direct interest to the phenomenology, regarding, in particular, the so-called microphysical parameters used in phenomenological studies.",

keywords = "Collisionless shock in plasma, Cosmic ray acceleration, Plasma microinstabilities, Shock waves and discontinuities",

author = "Arno Vanthieghem and Martin Lemoine and Illya Plotnikov and Anna Grassi and Mickael Grech and Laurent Gremillet and Guy Pelletier",

note = "Publisher Copyright: {\textcopyright} 2020 by the authors.",

year = "2020",

month = jun,

day = "1",

doi = "10.3390/GALAXIES8020033",

language = "English",

volume = "8",

journal = "Galaxies",

issn = "2075-4434",

number = "2",

}

TY - JOUR

T1 - Physics and phenomenology ofweakly magnetized, relativistic astrophysical shock waves

AU - Vanthieghem, Arno

AU - Lemoine, Martin

AU - Plotnikov, Illya

AU - Grassi, Anna

AU - Grech, Mickael

AU - Gremillet, Laurent

AU - Pelletier, Guy

PY - 2020/6/1

Y1 - 2020/6/1

N2 - Weakly magnetized, relativistic collisionless shock waves are not only the natural offsprings of relativistic jets in high-energy astrophysical sources, they are also associated with some of the most outstanding displays of energy dissipation through particle acceleration and radiation. Perhaps their most peculiar and exciting feature is that the magnetized turbulence that sustains the acceleration process, and (possibly) the secondary radiation itself, is self-excited by the accelerated particles themselves, so that the phenomenology of these shock waves hinges strongly on the microphysics of the shock. In this review, we draw a status report of this microphysics, benchmarking analytical arguments with particle-in-cell simulations, and extract consequences of direct interest to the phenomenology, regarding, in particular, the so-called microphysical parameters used in phenomenological studies.

AB - Weakly magnetized, relativistic collisionless shock waves are not only the natural offsprings of relativistic jets in high-energy astrophysical sources, they are also associated with some of the most outstanding displays of energy dissipation through particle acceleration and radiation. Perhaps their most peculiar and exciting feature is that the magnetized turbulence that sustains the acceleration process, and (possibly) the secondary radiation itself, is self-excited by the accelerated particles themselves, so that the phenomenology of these shock waves hinges strongly on the microphysics of the shock. In this review, we draw a status report of this microphysics, benchmarking analytical arguments with particle-in-cell simulations, and extract consequences of direct interest to the phenomenology, regarding, in particular, the so-called microphysical parameters used in phenomenological studies.

KW - Collisionless shock in plasma

KW - Cosmic ray acceleration

KW - Plasma microinstabilities

KW - Shock waves and discontinuities

U2 - 10.3390/GALAXIES8020033

DO - 10.3390/GALAXIES8020033

M3 - Review article

AN - SCOPUS:85084648708

SN - 2075-4434

VL - 8

JO - Galaxies

JF - Galaxies

IS - 2

M1 - 33

ER -

Physics and phenomenology ofweakly magnetized, relativistic astrophysical shock waves

Abstract

Keywords

Access to Document

Fingerprint

Cite this