Free electron lasers driven by plasma accelerators: status and near-term prospects

Emma, Claudio; Tilborg, J. van; Aßmann, Ralph; Barber, Sam; Cianchi, A.; Corde, S.; Couprie, Marie-Emmanuelle; D’Arcy, Richard; Ferrario, M.; Habib, A. F.; Hidding, B.; Hogan, Mark; Schroeder, Carl; Marinelli, Agostino; Labat, M.; Li, R.; li, chen; Loulergue, Alexandre; Osterhoff, Jens; Maier, Andreas R.; McNeil, B. W. J.; Wang, Wei

doi:10.1017/hpl.2021.39

Cited by 22 publications

(15 citation statements)

References 88 publications

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“…Ingenious post-plasma compensation approaches have been developed to address individual beam quality limitations, i.e. compensation of energy spread constraints or increasing peak current post-beam generation 16 – 26 , with efforts focused on working towards soft X-ray FEL demonstration 27 . The most advanced experimental success so far has been the recent demonstration of FEL gain in the EUV 28 and IR 29 range and seeded FEL 30 .…”

Section: Introductionmentioning

confidence: 99%

Attosecond-Angstrom free-electron-laser towards the cold beam limit

et al. 2023

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Electron beam quality is paramount for X-ray pulse production in free-electron-lasers (FELs). State-of-the-art linear accelerators (linacs) can deliver multi-GeV electron beams with sufficient quality for hard X-ray-FELs, albeit requiring km-scale setups, whereas plasma-based accelerators can produce multi-GeV electron beams on metre-scale distances, and begin to reach beam qualities sufficient for EUV FELs. Here we show, that electron beams from plasma photocathodes many orders of magnitude brighter than state-of-the-art can be generated in plasma wakefield accelerators (PWFAs), and then extracted, captured, transported and injected into undulators without significant quality loss. These ultrabright, sub-femtosecond electron beams can drive hard X-FELs near the cold beam limit to generate coherent X-ray pulses of attosecond-Angstrom class, reaching saturation after only 10 metres of undulator. This plasma-X-FEL opens pathways for advanced photon science capabilities, such as unperturbed observation of electronic motion inside atoms at their natural time and length scale, and towards higher photon energies.

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Section: Introductionmentioning

confidence: 99%

Attosecond-Angstrom free-electron-laser towards the cold beam limit

et al. 2023

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Section: Introductionmentioning

confidence: 99%

“…From the early stage of tens of percent level energy spread and few mm mrad-level emittance, LWFA electron beams have now achieved electron beams with nC-level charge [ 4 , 5 ] , few per-mille-level relative energy spread [ 6 – 9 ] and sub-mm mrad-level emittance [ 10 ] . Benefitted from the ultra-high acceleration gradient of LWFA [ 11 – 15 ] , ultra-compact radiation sources, such as betatron radiation [ 16 – 18 ] , Compton scattering [ 19 – 22 ] and tabletop free electron lasers (FELs) [ 23 – 25 ] , injectors for future colliders [ 26 ] will be possible. Most LWFA-based applications require an excellent 6D electron beam brightness [ 27 , 28 ] , defined by , where is the peak current, is the relative energy spread and and are the normalized transverse emittance of the electron beam.…”

Section: Introductionmentioning

confidence: 99%

“…From the early stage of tens of percent level energy spread and few mm mrad-level emittance, LWFA electron beams have now achieved electron beams with nC-level charge [4,5] , few per-mille-level relative energy spread [6][7][8][9] and sub-mm mrad-level emittance [10] . Benefitted from the ultra-high acceleration gradient of LWFA [11][12][13][14][15] , ultracompact radiation sources, such as betatron radiation [16][17][18] , Compton scattering [19][20][21][22] and tabletop free electron lasers (FELs) [23][24][25] , injectors for future colliders [26] will be possible. Most LWFA-based applications require an excellent 6D electron beam brightness [27,28] , defined by B 6D = I P ε nx ε ny σ γ •0.1% , where I P is the peak current, σ γ is the relative energy spread and ε nx and ε ny are the normalized Correspondence to: Ke Feng, Wentao Wang, and Ruxin Li, State Key Laboratory of High Field Laser Physics and CAS Center for Excellence in Ultra-intense Laser Science, Shanghai Institute of Optics and Fine Mechanics (SIOM), Chinese Academy of Sciences (CAS), Shanghai 201800, China.…”

Section: Introductionmentioning

confidence: 99%

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Measurement of electron beam transverse slice emittance using a focused beamline

Jiang

Feng

Wang

et al. 2023

High Pow Laser Sci Eng

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A single-shot measurement of electron emittance was experimentally accomplished using a focused transfer line with a dipole. The betatron phase of electrons based on laser wakefield acceleration (LWFA) is energy dependent owing to the coupling of the longitudinal acceleration field and the transverse focusing (defocusing) field in the bubble. Phase space presents slice information after phase compensation relative to the center energy. Fitting the transverse size of the electron beam at different energy slices in the energy spectrum measured 0.27 mm mrad in the experiment. Diagnosis of slice emittance facilitates local electron quality manipulation, which is important for the development of LWFA-based free electron lasers. The quasi-3D PIC simulations matched the experimental results and analysis well.

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“…Ingenious post-plasma compensation approaches have been developed to address individual beam quality limitations, i.e. compensation of energy spread constraints, or increasing peak current post beam generation 16,17,18,19,20,21,22,23,24,25,26 , with efforts focused working towards soft X-ray FEL demonstration 27 . The most advanced experimental success so far has been the recent demonstration of FEL gain in the EUV 28 and IR 29 range.…”

mentioning

confidence: 99%

Attosecond-Angstrom free-electron-laser towards the cold beam limit

Habib

Manahan

Scherkl

et al. 2022

Preprint

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Electron beam quality is paramount for X-ray pulse production in free-electron-lasers (FELs). State-of-the-art linear accelerators (linacs) can deliver multi-GeV electron beams with sufficient quality for hard X-ray-FELs, albeit requiring km-scale setups, whereas plasma-based accelerators can produce multi-GeV electron beams on metre-scale distances, and begin to reach beam qualities sufficient for EUV FELs. We show, that electron beams from plasma photocathodes many orders of magnitude brighter than state-of-the-art can be generated in plasma wakefieldaccelerators (PWFA), and then extracted, captured, transported and injected into undulators without quality loss. These ultrabright, sub-femtosecond electron beams can drive hard X-FELs near the cold beam limit to generate coherent X-ray pulses of attosecond-Angstrom class, reaching saturation after only 10 metres of undulator. This plasma-X-FEL opens pathways for novel photon science capabilities, such as unperturbed observation of electronic motion inside atoms at their natural time and length scale, and towards higher photon energies.

show abstract

Free electron lasers driven by plasma accelerators: status and near-term prospects

Cited by 22 publications

References 88 publications

Attosecond-Angstrom free-electron-laser towards the cold beam limit

Attosecond-Angstrom free-electron-laser towards the cold beam limit

Measurement of electron beam transverse slice emittance using a focused beamline

Attosecond-Angstrom free-electron-laser towards the cold beam limit

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