Coxinel transport of laser plasma accelerated electrons

Driss Oumbarek Espinos; Amin Ghaith; Alexandre Loulergue; Thomas AndrÃ©; Charles Kitégi; Mourad Sebdaoui; Fabrice Marteau; Frédéric Blache; Mathieu Valleaú; Marie Labat; Alain Lestrade; Eleónore Roussel; Cédric Thaur; Sébastien Corde; Guillaume Lambert; Olena Kononenko; Jean Philippe Goddet; Amar Tafzi; Igor Andriyash; Victor Malka; Marie Emmanuelle Couprie

doi:10.1088/1361-6587/ab5fec

Coxinel transport of laser plasma accelerated electrons

Driss Oumbarek Espinos
, Amin Ghaith
, Alexandre Loulergue
, Thomas AndrÃ©
, Charles Kitégi
, Mourad Sebdaoui
, Fabrice Marteau
, Frédéric Blache
, Mathieu Valleaú
, Marie Labat
, Alain Lestrade
, Eleónore Roussel
, Cédric Thaur
, Sébastien Corde
, Guillaume Lambert
, Olena Kononenko
, Jean Philippe Goddet
, Amar Tafzi
, Igor Andriyash
, Victor Malka

Marie Emmanuelle Couprie

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

Abstract

Laser plasma acceleration (LPA) enables the generation of an up to several GeV electron beam with a short bunch length and high peak current within a centimeter scale. In view of undulator type light source applications, electron beam manipulation has to be applied. We report here on detailed electron beam transport for an LPA electron beam on the COXINEL test line, that consists of strong permanent quadrupoles to handle the electron beam divergence, a magnetic chicane to reduce the energy spread and a second set of quadrupoles for adjusting the focusing inside the undulator. After describing the measured LPA characteristics, we show that we can properly transport the electron beam along the line, thanks to several screens. We also illustrate the influence of the chromatic effects induced by the electron beam energy spread, both experimentally and numerically. We then study the sensitivity of the transport to the electron beam pointing and skewed quadrupolar components.

Original language	English
Article number	034001
Journal	Plasma Physics and Controlled Fusion
Volume	62
Issue number	3
DOIs	https://doi.org/10.1088/1361-6587/ab5fec
Publication status	Published - 1 Jan 2020

Keywords

Electron beam transport
Free electron laser
Laser plasma acceleration
Quadrupole

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Espinos, D. O., Ghaith, A., Loulergue, A., AndrÃ©, T., Kitégi, C., Sebdaoui, M., Marteau, F., Blache, F., Valleaú, M., Labat, M., Lestrade, A., Roussel, E., Thaur, C., Corde, S., Lambert, G., Kononenko, O., Goddet, J. P., Tafzi, A., Andriyash, I., ... Couprie, M. E. (2020). Coxinel transport of laser plasma accelerated electrons. Plasma Physics and Controlled Fusion, 62(3), Article 034001. https://doi.org/10.1088/1361-6587/ab5fec

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title = "Coxinel transport of laser plasma accelerated electrons",

abstract = "Laser plasma acceleration (LPA) enables the generation of an up to several GeV electron beam with a short bunch length and high peak current within a centimeter scale. In view of undulator type light source applications, electron beam manipulation has to be applied. We report here on detailed electron beam transport for an LPA electron beam on the COXINEL test line, that consists of strong permanent quadrupoles to handle the electron beam divergence, a magnetic chicane to reduce the energy spread and a second set of quadrupoles for adjusting the focusing inside the undulator. After describing the measured LPA characteristics, we show that we can properly transport the electron beam along the line, thanks to several screens. We also illustrate the influence of the chromatic effects induced by the electron beam energy spread, both experimentally and numerically. We then study the sensitivity of the transport to the electron beam pointing and skewed quadrupolar components.",

keywords = "Electron beam transport, Free electron laser, Laser plasma acceleration, Quadrupole",

author = "Espinos, \{Driss Oumbarek\} and Amin Ghaith and Alexandre Loulergue and Thomas Andr{\~A}{\textcopyright} and Charles Kit{\'e}gi and Mourad Sebdaoui and Fabrice Marteau and Fr{\'e}d{\'e}ric Blache and Mathieu Vallea{\'u} and Marie Labat and Alain Lestrade and Ele{\'o}nore Roussel and C{\'e}dric Thaur and S{\'e}bastien Corde and Guillaume Lambert and Olena Kononenko and Goddet, \{Jean Philippe\} and Amar Tafzi and Igor Andriyash and Victor Malka and Couprie, \{Marie Emmanuelle\}",

year = "2020",

month = jan,

day = "1",

doi = "10.1088/1361-6587/ab5fec",

language = "English",

volume = "62",

journal = "Plasma Physics and Controlled Fusion",

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Espinos, DO, Ghaith, A, Loulergue, A, AndrÃ©, T, Kitégi, C, Sebdaoui, M, Marteau, F, Blache, F, Valleaú, M, Labat, M, Lestrade, A, Roussel, E, Thaur, C, Corde, S , Lambert, G , Kononenko, O , Goddet, JP, Tafzi, A, Andriyash, I, Malka, V & Couprie, ME 2020, 'Coxinel transport of laser plasma accelerated electrons', Plasma Physics and Controlled Fusion, vol. 62, no. 3, 034001. https://doi.org/10.1088/1361-6587/ab5fec

TY - JOUR

T1 - Coxinel transport of laser plasma accelerated electrons

AU - Espinos, Driss Oumbarek

AU - Ghaith, Amin

AU - Loulergue, Alexandre

AU - AndrÃ©, Thomas

AU - Kitégi, Charles

AU - Sebdaoui, Mourad

AU - Marteau, Fabrice

AU - Blache, Frédéric

AU - Valleaú, Mathieu

AU - Labat, Marie

AU - Lestrade, Alain

AU - Roussel, Eleónore

AU - Thaur, Cédric

AU - Corde, Sébastien

AU - Lambert, Guillaume

AU - Kononenko, Olena

AU - Goddet, Jean Philippe

AU - Tafzi, Amar

AU - Andriyash, Igor

AU - Malka, Victor

AU - Couprie, Marie Emmanuelle

PY - 2020/1/1

Y1 - 2020/1/1

N2 - Laser plasma acceleration (LPA) enables the generation of an up to several GeV electron beam with a short bunch length and high peak current within a centimeter scale. In view of undulator type light source applications, electron beam manipulation has to be applied. We report here on detailed electron beam transport for an LPA electron beam on the COXINEL test line, that consists of strong permanent quadrupoles to handle the electron beam divergence, a magnetic chicane to reduce the energy spread and a second set of quadrupoles for adjusting the focusing inside the undulator. After describing the measured LPA characteristics, we show that we can properly transport the electron beam along the line, thanks to several screens. We also illustrate the influence of the chromatic effects induced by the electron beam energy spread, both experimentally and numerically. We then study the sensitivity of the transport to the electron beam pointing and skewed quadrupolar components.

AB - Laser plasma acceleration (LPA) enables the generation of an up to several GeV electron beam with a short bunch length and high peak current within a centimeter scale. In view of undulator type light source applications, electron beam manipulation has to be applied. We report here on detailed electron beam transport for an LPA electron beam on the COXINEL test line, that consists of strong permanent quadrupoles to handle the electron beam divergence, a magnetic chicane to reduce the energy spread and a second set of quadrupoles for adjusting the focusing inside the undulator. After describing the measured LPA characteristics, we show that we can properly transport the electron beam along the line, thanks to several screens. We also illustrate the influence of the chromatic effects induced by the electron beam energy spread, both experimentally and numerically. We then study the sensitivity of the transport to the electron beam pointing and skewed quadrupolar components.

KW - Electron beam transport

KW - Free electron laser

KW - Laser plasma acceleration

KW - Quadrupole

UR - https://www.scopus.com/pages/publications/85082728622

U2 - 10.1088/1361-6587/ab5fec

DO - 10.1088/1361-6587/ab5fec

M3 - Article

AN - SCOPUS:85082728622

SN - 0741-3335

VL - 62

JO - Plasma Physics and Controlled Fusion

JF - Plasma Physics and Controlled Fusion

IS - 3

M1 - 034001

ER -

Coxinel transport of laser plasma accelerated electrons

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Keywords

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