Numerical study of an FEL based on lwfa electrons and a laser-plasma wiggler

R. Lehe; G. Lambert; A. F. Lifschitz; V. Malka; J. M. Rax; X. Davoine

Numerical study of an FEL based on lwfa electrons and a laser-plasma wiggler

R. Lehe
, G. Lambert
, A. F. Lifschitz
, V. Malka
, J. M. Rax
, X. Davoine

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Recent works [1] have suggested that laser-wakefield acceleration (LWFA) may be used to produce the electron beam of an FEL, thereby considerably reducing the size and cost of the device. However, when using conventional magnetic wigglers, the requirements on the beam quality are very stringent, and are still challenging with current LWFA beams. An interesting alternative may be to use a laser-plasma wiggler (e.g. a plasma wave or a laser beam). Compared to a conventional wiggler, a laser-plasma wiggler has a field amplitude several orders of magnitude higher, as well as a correspondingly shorter wavelength - which may place lower constraints on the beam quality and eliminate the need for transport. Taking into account beam quality, beam transport and wiggler inhomogeneity, we evaluate the range of wiggler properties (field, wavelength) that would make the FEL radiation possible. From this analysis, the counterpropagating laser wiggler [2] seems to be one of the most promising solutions. We therefore extend the widely-used Ming Xie formula [3] (which was derived for a static, magnetic wiggler) to a counterpropagating laser wiggler. We use this formula to evaluate the potential use of current state-of-the-art lasers.

Original language	English
Title of host publication	FEL 2012 - 34th International Free Electron Laser Conference
Pages	642-645
Number of pages	4
Publication status	Published - 1 Dec 2012
Event	34th International Free Electron Laser Conference, FEL 2012 - Nara, Japan Duration: 26 Aug 2012 → 31 Aug 2012

Publication series

Name	FEL 2012 - 34th International Free Electron Laser Conference

Conference

Conference	34th International Free Electron Laser Conference, FEL 2012
Country/Territory	Japan
City	Nara
Period	26/08/12 → 31/08/12

Cite this

@inproceedings{ce21e2703bb4416ba431e2255f319fda,

title = "Numerical study of an FEL based on lwfa electrons and a laser-plasma wiggler",

abstract = "Recent works [1] have suggested that laser-wakefield acceleration (LWFA) may be used to produce the electron beam of an FEL, thereby considerably reducing the size and cost of the device. However, when using conventional magnetic wigglers, the requirements on the beam quality are very stringent, and are still challenging with current LWFA beams. An interesting alternative may be to use a laser-plasma wiggler (e.g. a plasma wave or a laser beam). Compared to a conventional wiggler, a laser-plasma wiggler has a field amplitude several orders of magnitude higher, as well as a correspondingly shorter wavelength - which may place lower constraints on the beam quality and eliminate the need for transport. Taking into account beam quality, beam transport and wiggler inhomogeneity, we evaluate the range of wiggler properties (field, wavelength) that would make the FEL radiation possible. From this analysis, the counterpropagating laser wiggler [2] seems to be one of the most promising solutions. We therefore extend the widely-used Ming Xie formula [3] (which was derived for a static, magnetic wiggler) to a counterpropagating laser wiggler. We use this formula to evaluate the potential use of current state-of-the-art lasers.",

author = "R. Lehe and G. Lambert and Lifschitz, \{A. F.\} and V. Malka and Rax, \{J. M.\} and X. Davoine",

year = "2012",

month = dec,

day = "1",

language = "English",

isbn = "9783954501236",

series = "FEL 2012 - 34th International Free Electron Laser Conference",

pages = "642--645",

booktitle = "FEL 2012 - 34th International Free Electron Laser Conference",

note = "34th International Free Electron Laser Conference, FEL 2012 ; Conference date: 26-08-2012 Through 31-08-2012",

}

Lehe, R, Lambert, G, Lifschitz, AF, Malka, V, Rax, JM & Davoine, X 2012, Numerical study of an FEL based on lwfa electrons and a laser-plasma wiggler. in FEL 2012 - 34th International Free Electron Laser Conference. FEL 2012 - 34th International Free Electron Laser Conference, pp. 642-645, 34th International Free Electron Laser Conference, FEL 2012, Nara, Japan, 26/08/12.

Numerical study of an FEL based on lwfa electrons and a laser-plasma wiggler. / Lehe, R.; Lambert, G.; Lifschitz, A. F. et al.
FEL 2012 - 34th International Free Electron Laser Conference. 2012. p. 642-645 (FEL 2012 - 34th International Free Electron Laser Conference).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Numerical study of an FEL based on lwfa electrons and a laser-plasma wiggler

AU - Lehe, R.

AU - Lambert, G.

AU - Lifschitz, A. F.

AU - Malka, V.

AU - Rax, J. M.

AU - Davoine, X.

PY - 2012/12/1

Y1 - 2012/12/1

N2 - Recent works [1] have suggested that laser-wakefield acceleration (LWFA) may be used to produce the electron beam of an FEL, thereby considerably reducing the size and cost of the device. However, when using conventional magnetic wigglers, the requirements on the beam quality are very stringent, and are still challenging with current LWFA beams. An interesting alternative may be to use a laser-plasma wiggler (e.g. a plasma wave or a laser beam). Compared to a conventional wiggler, a laser-plasma wiggler has a field amplitude several orders of magnitude higher, as well as a correspondingly shorter wavelength - which may place lower constraints on the beam quality and eliminate the need for transport. Taking into account beam quality, beam transport and wiggler inhomogeneity, we evaluate the range of wiggler properties (field, wavelength) that would make the FEL radiation possible. From this analysis, the counterpropagating laser wiggler [2] seems to be one of the most promising solutions. We therefore extend the widely-used Ming Xie formula [3] (which was derived for a static, magnetic wiggler) to a counterpropagating laser wiggler. We use this formula to evaluate the potential use of current state-of-the-art lasers.

AB - Recent works [1] have suggested that laser-wakefield acceleration (LWFA) may be used to produce the electron beam of an FEL, thereby considerably reducing the size and cost of the device. However, when using conventional magnetic wigglers, the requirements on the beam quality are very stringent, and are still challenging with current LWFA beams. An interesting alternative may be to use a laser-plasma wiggler (e.g. a plasma wave or a laser beam). Compared to a conventional wiggler, a laser-plasma wiggler has a field amplitude several orders of magnitude higher, as well as a correspondingly shorter wavelength - which may place lower constraints on the beam quality and eliminate the need for transport. Taking into account beam quality, beam transport and wiggler inhomogeneity, we evaluate the range of wiggler properties (field, wavelength) that would make the FEL radiation possible. From this analysis, the counterpropagating laser wiggler [2] seems to be one of the most promising solutions. We therefore extend the widely-used Ming Xie formula [3] (which was derived for a static, magnetic wiggler) to a counterpropagating laser wiggler. We use this formula to evaluate the potential use of current state-of-the-art lasers.

M3 - Conference contribution

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SN - 9783954501236

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BT - FEL 2012 - 34th International Free Electron Laser Conference

T2 - 34th International Free Electron Laser Conference, FEL 2012

Y2 - 26 August 2012 through 31 August 2012

ER -

Numerical study of an FEL based on lwfa electrons and a laser-plasma wiggler

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