Coherent startup of an infrared free-electron laser

Jaroszynski, D. A.; Bakker, R.J.; Meer, A. F. G. van der; Oepts, D.; Amersfoort, P.W. van

doi:10.1103/physrevlett.71.3798

Cited by 97 publications

(35 citation statements)

References 7 publications

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“…Longer wavelength systems have demonstrated that bunch rise times $10k/c, where c is the speed of light in vacuum, are sufficiently rapid to seed self-amplified coherent spontaneous emission (SACSE) in FELs. 28,29 At k ¼ 150 nm, for example, this corresponds to a threshold rise time $5 fs. For our beam line setup as modelled in Fig.…”

Section: Applied Physics Lettersmentioning

confidence: 99%

An ultrashort pulse ultra-violet radiation undulator source driven by a laser plasma wakefield accelerator

Anania

Brunetti

Wiggins

et al. 2014

Applied Physics Letters

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Section: Applied Physics Lettersmentioning

confidence: 99%

An ultrashort pulse ultra-violet radiation undulator source driven by a laser plasma wakefield accelerator

Anania

Brunetti

Wiggins

et al. 2014

Applied Physics Letters

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“…This large amount of spontaneous emission shown by short beams was first observed in Refs. [22,23], studied then in detail in [18,19,24,25] and connected with the presence of large gradients in the current profile. One could advance a possible alternative explanation of this enhanced spontaneous emission by the following reasoning.…”

Section: Numerical Resultsmentioning

confidence: 98%

One-dimensional free-electron laser equations without the slowly varying envelope approximation

Maroli

Petrillo

Ferrario

2011

Phys. Rev. ST Accel. Beams

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A set of one-dimensional equations has been deduced in the time domain from the Maxwell-Lorentz system with the aim of describing the free-electron laser radiation without using the slowly varying envelope approximation (SVEA). These equations are valid even in the case of arbitrarily short electron bunches and of current distributions with ripples on the scale of or shorter than the wavelength. Numerical examples are presented, showing that for long homogeneous bunches the new set of equations gives results in agreement with the SVEA free-electron laser theory and that the use of short or prebunched electron beams leads to a decrease of the emission lethargy. Furthermore, we demonstrate that in all cases in which the backward low frequency wave has negligible effects, these equations can be reduced to a form similar to the usual 1D SVEA equations but with a different definition of the bunching term.

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“…There are two new candidates for generating high power THz radiation. One is accelerator-based radiation, such as coherent synchrotron radiation [11,12], coherent transition radiation [13], free electron laser [14], Cherenkov radiation [15] and Smith-Purcell effect [16], etc. These facilities can provide a high average power output tunable at a very broad band.…”

Section: Introductionmentioning

confidence: 99%

Angular distribution of terahertz emission from laser interactions with solid targets

Zhou

et al. 2011

Sci. China Inf. Sci.

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Intense femtosecond laser-plasma interactions can produce high power terahertz radiations. In our experiment, the polished copper target was irradiated by a p-polarized laser with intensity of more than 10 18 W/cm 2 at an incident angle of 67.5 • from the target normal. The THz energy from three different detection angles is measured. The maximum emission is found in the direction at an angle of 45 • to the laser backward direction, which is more than one order of magnitude higher than in the other two directions. A simple theoretical model has been established to explain the measurements.

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Coherent startup of an infrared free-electron laser

Cited by 97 publications

References 7 publications

An ultrashort pulse ultra-violet radiation undulator source driven by a laser plasma wakefield accelerator

An ultrashort pulse ultra-violet radiation undulator source driven by a laser plasma wakefield accelerator

One-dimensional free-electron laser equations without the slowly varying envelope approximation

Angular distribution of terahertz emission from laser interactions with solid targets

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