Acceleration of injected electrons in a laser wakefield experiment

F. Dorchies; F. Amiranoff; V. Malka; J. R. Marquès; A. Modena; D. Bernard; F. Jacquet; Ph Miné; B. Gros; G. Matthieussent; P. Mora; A. Solodov; J. Morillo; Z. Najmudin

doi:10.1063/1.873248

Acceleration of injected electrons in a laser wakefield experiment

F. Dorchies
, F. Amiranoff
, V. Malka
, J. R. Marquès
, A. Modena
, D. Bernard
, F. Jacquet
, Ph Miné
, B. Gros
, G. Matthieussent
, P. Mora
, A. Solodov
, J. Morillo
, Z. Najmudin

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

Résumé

An electron plasma wave (EPW) has been excited by a short laser pulse (5 J, 400 fs) via the laser wakefield (LWF) mechanism. At the LWF quasi-resonance condition, the 3 MeV injected electrons have been accelerated with a maximum energy gain of 1.5 MeV. The maximum longitudinal electric field is estimated to be 1.5 GV/m. It has been observed that electrons deflected during the interaction, can scatter on the walls of the experimental chamber and fake a high energy signal. A special effort has been given in the electron detection to separate the accelerated electrons signal from the background noise. The experimental data are confirmed with numerical simulations, demonstrating that the energy gain is affected by the EPW radial electric field. The duration of the EPW inferred by the number of accelerated electrons and by the numerical simulations is of the order Of 1-10 ps

langue originale	Anglais
Pages (de - à)	2903-2913
Nombre de pages	11
journal	Physics of Plasmas
Volume	6
Numéro de publication	7
Les DOIs	https://doi.org/10.1063/1.873248
état	Publié - 1 janv. 1999

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title = "Acceleration of injected electrons in a laser wakefield experiment",

abstract = "An electron plasma wave (EPW) has been excited by a short laser pulse (5 J, 400 fs) via the laser wakefield (LWF) mechanism. At the LWF quasi-resonance condition, the 3 MeV injected electrons have been accelerated with a maximum energy gain of 1.5 MeV. The maximum longitudinal electric field is estimated to be 1.5 GV/m. It has been observed that electrons deflected during the interaction, can scatter on the walls of the experimental chamber and fake a high energy signal. A special effort has been given in the electron detection to separate the accelerated electrons signal from the background noise. The experimental data are confirmed with numerical simulations, demonstrating that the energy gain is affected by the EPW radial electric field. The duration of the EPW inferred by the number of accelerated electrons and by the numerical simulations is of the order Of 1-10 ps",

author = "F. Dorchies and F. Amiranoff and V. Malka and Marqu{\`e}s, \{J. R.\} and A. Modena and D. Bernard and F. Jacquet and Ph Min{\'e} and B. Gros and G. Matthieussent and P. Mora and A. Solodov and J. Morillo and Z. Najmudin",

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month = jan,

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doi = "10.1063/1.873248",

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TY - JOUR

T1 - Acceleration of injected electrons in a laser wakefield experiment

AU - Dorchies, F.

AU - Amiranoff, F.

AU - Malka, V.

AU - Marquès, J. R.

AU - Modena, A.

AU - Bernard, D.

AU - Jacquet, F.

AU - Miné, Ph

AU - Gros, B.

AU - Matthieussent, G.

AU - Mora, P.

AU - Solodov, A.

AU - Morillo, J.

AU - Najmudin, Z.

PY - 1999/1/1

Y1 - 1999/1/1

N2 - An electron plasma wave (EPW) has been excited by a short laser pulse (5 J, 400 fs) via the laser wakefield (LWF) mechanism. At the LWF quasi-resonance condition, the 3 MeV injected electrons have been accelerated with a maximum energy gain of 1.5 MeV. The maximum longitudinal electric field is estimated to be 1.5 GV/m. It has been observed that electrons deflected during the interaction, can scatter on the walls of the experimental chamber and fake a high energy signal. A special effort has been given in the electron detection to separate the accelerated electrons signal from the background noise. The experimental data are confirmed with numerical simulations, demonstrating that the energy gain is affected by the EPW radial electric field. The duration of the EPW inferred by the number of accelerated electrons and by the numerical simulations is of the order Of 1-10 ps

AB - An electron plasma wave (EPW) has been excited by a short laser pulse (5 J, 400 fs) via the laser wakefield (LWF) mechanism. At the LWF quasi-resonance condition, the 3 MeV injected electrons have been accelerated with a maximum energy gain of 1.5 MeV. The maximum longitudinal electric field is estimated to be 1.5 GV/m. It has been observed that electrons deflected during the interaction, can scatter on the walls of the experimental chamber and fake a high energy signal. A special effort has been given in the electron detection to separate the accelerated electrons signal from the background noise. The experimental data are confirmed with numerical simulations, demonstrating that the energy gain is affected by the EPW radial electric field. The duration of the EPW inferred by the number of accelerated electrons and by the numerical simulations is of the order Of 1-10 ps

UR - https://www.scopus.com/pages/publications/0000441049

U2 - 10.1063/1.873248

DO - 10.1063/1.873248

M3 - Article

AN - SCOPUS:0000441049

SN - 1070-664X

VL - 6

SP - 2903

EP - 2913

JO - Physics of Plasmas

JF - Physics of Plasmas

IS - 7

ER -

Acceleration of injected electrons in a laser wakefield experiment

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