Probing ultrafast magnetic-field generation by current filamentation instability in femtosecond relativistic laser-matter interactions

G. Raj; O. Kononenko; M. F. Gilljohann; A. Doche; X. Davoine; C. Caizergues; Y. Y. Chang; J. P. Couperus Cabadaǧ; A. Debus; H. Ding; M. Förster; J. P. Goddet; T. Heinemann; T. Kluge; T. Kurz; R. Pausch; P. Rousseau; P. San Miguel Claveria; S. Schöbel; A. Siciak; K. Steiniger; A. Tafzi; S. Yu; B. Hidding; A. Martinez De La Ossa; A. Irman; S. Karsch; A. Döpp; U. Schramm; L. Gremillet; S. Corde

doi:10.1103/PhysRevResearch.2.023123

Probing ultrafast magnetic-field generation by current filamentation instability in femtosecond relativistic laser-matter interactions

G. Raj
, O. Kononenko
, M. F. Gilljohann
, A. Doche
, X. Davoine
, C. Caizergues
, Y. Y. Chang
, J. P. Couperus Cabadaǧ
, A. Debus
, H. Ding
, M. Förster
, J. P. Goddet
, T. Heinemann
, T. Kluge
, T. Kurz
, R. Pausch
, P. Rousseau
, P. San Miguel Claveria
, S. Schöbel
, A. Siciak

K. Steiniger, A. Tafzi, S. Yu, B. Hidding, A. Martinez De La Ossa, A. Irman, S. Karsch, A. Döpp, U. Schramm, L. Gremillet, S. Corde

Laboratory d'Optique Appliquée, ENSTA, CNRS-École Polytechnique
Universität München
Max-Planck Institut für Quantenoptik
CEA/UVSQ/CNRS
Institute of Radiooncology - OncoRay
c/o DESY
University of Strathclyde
Sci-Tech Daresbury
Technical University Dresden

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

The current filamentation instability is a key phenomenon underpinning various processes in astrophysics, laboratory laser-plasma, and beam-plasma experiments. Here we show that the ultrafast dynamics of this instability can be explored in the context of relativistic laser-solid interactions through deflectometry by low-emittance, highly relativistic electron bunches from a laser wakefield accelerator. We present experimental measurements of the femtosecond timescale generation of strong magnetic-field fluctuations, with a measured line-integrated B field of 2.70±0.39kTμm. Three-dimensional, fully relativistic particle-in-cell simulations demonstrate that such fluctuations originate from the current filamentation instability arising at submicron scales around the irradiated target surface, and that they grow to amplitudes strong enough to broaden the angular distribution of the probe electron bunch a few tens of femtoseconds after the laser pulse maximum. Our results open a branch of physics experiments investigating the femtosecond dynamics of laser-driven plasma instabilities by means of synchronized, wakefield-accelerated electron beams.

langue originale	Anglais
Numéro d'article	023123
journal	Physical Review Research
Volume	2
Numéro de publication	2
Les DOIs	https://doi.org/10.1103/PhysRevResearch.2.023123
état	Publié - 4 mai 2020

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10.1103/PhysRevResearch.2.023123

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Raj, G., Kononenko, O., Gilljohann, M. F., Doche, A., Davoine, X., Caizergues, C., Chang, Y. Y., Couperus Cabadaǧ, J. P., Debus, A., Ding, H., Förster, M., Goddet, J. P., Heinemann, T., Kluge, T., Kurz, T., Pausch, R., Rousseau, P., San Miguel Claveria, P., Schöbel, S., ... Corde, S. (2020). Probing ultrafast magnetic-field generation by current filamentation instability in femtosecond relativistic laser-matter interactions. Physical Review Research, 2(2), Article 023123. https://doi.org/10.1103/PhysRevResearch.2.023123

@article{5b14848b06a947d9ab60d8ace0028187,

title = "Probing ultrafast magnetic-field generation by current filamentation instability in femtosecond relativistic laser-matter interactions",

abstract = "The current filamentation instability is a key phenomenon underpinning various processes in astrophysics, laboratory laser-plasma, and beam-plasma experiments. Here we show that the ultrafast dynamics of this instability can be explored in the context of relativistic laser-solid interactions through deflectometry by low-emittance, highly relativistic electron bunches from a laser wakefield accelerator. We present experimental measurements of the femtosecond timescale generation of strong magnetic-field fluctuations, with a measured line-integrated B field of 2.70±0.39kTμm. Three-dimensional, fully relativistic particle-in-cell simulations demonstrate that such fluctuations originate from the current filamentation instability arising at submicron scales around the irradiated target surface, and that they grow to amplitudes strong enough to broaden the angular distribution of the probe electron bunch a few tens of femtoseconds after the laser pulse maximum. Our results open a branch of physics experiments investigating the femtosecond dynamics of laser-driven plasma instabilities by means of synchronized, wakefield-accelerated electron beams.",

author = "G. Raj and O. Kononenko and Gilljohann, \{M. F.\} and A. Doche and X. Davoine and C. Caizergues and Chang, \{Y. Y.\} and \{Couperus Cabadaǧ\}, \{J. P.\} and A. Debus and H. Ding and M. F{\"o}rster and Goddet, \{J. P.\} and T. Heinemann and T. Kluge and T. Kurz and R. Pausch and P. Rousseau and \{San Miguel Claveria\}, P. and S. Sch{\"o}bel and A. Siciak and K. Steiniger and A. Tafzi and S. Yu and B. Hidding and \{Martinez De La Ossa\}, A. and A. Irman and S. Karsch and A. D{\"o}pp and U. Schramm and L. Gremillet and S. Corde",

note = "Publisher Copyright: {\textcopyright} 2020 American Physical Society.",

year = "2020",

month = may,

day = "4",

doi = "10.1103/PhysRevResearch.2.023123",

language = "English",

volume = "2",

journal = "Physical Review Research",

issn = "2643-1564",

number = "2",

}

Raj, G, Kononenko, O, Gilljohann, MF, Doche, A, Davoine, X, Caizergues, C, Chang, YY, Couperus Cabadaǧ, JP, Debus, A, Ding, H, Förster, M, Goddet, JP, Heinemann, T, Kluge, T, Kurz, T, Pausch, R, Rousseau, P, San Miguel Claveria, P, Schöbel, S, Siciak, A, Steiniger, K, Tafzi, A, Yu, S, Hidding, B, Martinez De La Ossa, A, Irman, A, Karsch, S, Döpp, A, Schramm, U, Gremillet, L & Corde, S 2020, 'Probing ultrafast magnetic-field generation by current filamentation instability in femtosecond relativistic laser-matter interactions', Physical Review Research, VOL. 2, Numéro 2, 023123. https://doi.org/10.1103/PhysRevResearch.2.023123

TY - JOUR

T1 - Probing ultrafast magnetic-field generation by current filamentation instability in femtosecond relativistic laser-matter interactions

AU - Raj, G.

AU - Kononenko, O.

AU - Gilljohann, M. F.

AU - Doche, A.

AU - Davoine, X.

AU - Caizergues, C.

AU - Chang, Y. Y.

AU - Couperus Cabadaǧ, J. P.

AU - Debus, A.

AU - Ding, H.

AU - Förster, M.

AU - Goddet, J. P.

AU - Heinemann, T.

AU - Kluge, T.

AU - Kurz, T.

AU - Pausch, R.

AU - Rousseau, P.

AU - San Miguel Claveria, P.

AU - Schöbel, S.

AU - Siciak, A.

AU - Steiniger, K.

AU - Tafzi, A.

AU - Yu, S.

AU - Hidding, B.

AU - Martinez De La Ossa, A.

AU - Irman, A.

AU - Karsch, S.

AU - Döpp, A.

AU - Schramm, U.

AU - Gremillet, L.

AU - Corde, S.

PY - 2020/5/4

Y1 - 2020/5/4

N2 - The current filamentation instability is a key phenomenon underpinning various processes in astrophysics, laboratory laser-plasma, and beam-plasma experiments. Here we show that the ultrafast dynamics of this instability can be explored in the context of relativistic laser-solid interactions through deflectometry by low-emittance, highly relativistic electron bunches from a laser wakefield accelerator. We present experimental measurements of the femtosecond timescale generation of strong magnetic-field fluctuations, with a measured line-integrated B field of 2.70±0.39kTμm. Three-dimensional, fully relativistic particle-in-cell simulations demonstrate that such fluctuations originate from the current filamentation instability arising at submicron scales around the irradiated target surface, and that they grow to amplitudes strong enough to broaden the angular distribution of the probe electron bunch a few tens of femtoseconds after the laser pulse maximum. Our results open a branch of physics experiments investigating the femtosecond dynamics of laser-driven plasma instabilities by means of synchronized, wakefield-accelerated electron beams.

AB - The current filamentation instability is a key phenomenon underpinning various processes in astrophysics, laboratory laser-plasma, and beam-plasma experiments. Here we show that the ultrafast dynamics of this instability can be explored in the context of relativistic laser-solid interactions through deflectometry by low-emittance, highly relativistic electron bunches from a laser wakefield accelerator. We present experimental measurements of the femtosecond timescale generation of strong magnetic-field fluctuations, with a measured line-integrated B field of 2.70±0.39kTμm. Three-dimensional, fully relativistic particle-in-cell simulations demonstrate that such fluctuations originate from the current filamentation instability arising at submicron scales around the irradiated target surface, and that they grow to amplitudes strong enough to broaden the angular distribution of the probe electron bunch a few tens of femtoseconds after the laser pulse maximum. Our results open a branch of physics experiments investigating the femtosecond dynamics of laser-driven plasma instabilities by means of synchronized, wakefield-accelerated electron beams.

U2 - 10.1103/PhysRevResearch.2.023123

DO - 10.1103/PhysRevResearch.2.023123

M3 - Article

AN - SCOPUS:85094629816

SN - 2643-1564

VL - 2

JO - Physical Review Research

JF - Physical Review Research

IS - 2

M1 - 023123

ER -

Probing ultrafast magnetic-field generation by current filamentation instability in femtosecond relativistic laser-matter interactions

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