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000292783 0247_ $$2doi$$a10.1103/PhysRevSTAB.18.120102
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000292783 1001_ $$0P:(DE-H253)PIP1013696$$aZeitler, Benno$$b0$$eCorresponding author
000292783 245__ $$aLinearization of the Longitudinal Phase Space without Higher Harmonic Field
000292783 260__ $$a[S.l.]$$bSoc.$$c2015
000292783 264_1 $$2Crossref$$3online$$bAmerican Physical Society (APS)$$c2015-12-30
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000292783 520__ $$aAccelerator applications like free-electron lasers, time-resolved electron diffraction, and advanced accelerator concepts like plasma acceleration desire bunches of ever shorter longitudinal extent. However, apart from space charge repulsion, the internal bunch structure and its development along the beam line can limit the achievable compression due to nonlinear phase space correlations. In order to improve such a limited longitudinal focus, a correction by properly linearizing the phase space is required. At large scale facilities like Flash at DESY or the European XFEL, a higher harmonic cavity is installed for this purpose. In this paper, another method is described and evaluated: Expanding the beam after the electron source enables a higher order correction of the longitudinal focus by a subsequent accelerating cavity which is operated at the same frequency as the electron gun. The elaboration of this idea presented here is based on a ballistic bunching scheme, but can be extended to bunch compression based on magnetic chicanes. The core of this article is an analytic model describing this approach, which is verified by simulations, predicting possible bunch length below 1 fs at low bunch charge. Minimizing the energy spread down to σE/E<10−5 while keeping the bunch long is another interesting possibility, which finds applications, e.g., in time resolved transmission electron microscopy concepts.
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000292783 7001_ $$0P:(DE-H253)PIP1002625$$aFloettmann, Klaus$$b1$$udesy
000292783 7001_ $$0P:(DE-H253)PIP1013695$$aGrüner, Florian$$b2
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000292783 999C5 $$1M. Hada$$2Crossref$$oM. Hada Research in Optical Sciences 2012$$tResearch in Optical Sciences$$y2012
000292783 999C5 $$2Crossref$$9-- missing cx lookup --$$a10.1016/j.nima.2013.12.031
000292783 999C5 $$2Crossref$$9-- missing cx lookup --$$a10.1103/PhysRevSTAB.18.032802
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000292783 999C5 $$1E. Vogel$$2Crossref$$oE. Vogel Proceedings of the International Particle Accelerator Conference, Kyoto, Japan 2010$$tProceedings of the International Particle Accelerator Conference, Kyoto, Japan$$y2010
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000292783 999C5 $$1B. Zeitler$$2Crossref$$oB. Zeitler SPIE Optics + Optoelectronics 2013$$tSPIE Optics + Optoelectronics$$y2013
000292783 999C5 $$2Crossref$$9-- missing cx lookup --$$a10.1103/PhysRevSTAB.18.064801
000292783 999C5 $$2Crossref$$9-- missing cx lookup --$$a10.1103/PhysRevApplied.2.024003
000292783 999C5 $$2Crossref$$9-- missing cx lookup --$$a10.1016/j.nima.2014.05.068
000292783 999C5 $$2Crossref$$9-- missing cx lookup --$$a10.1103/PhysRevE.55.7565
000292783 999C5 $$2Crossref$$9-- missing cx lookup --$$a10.1063/1.50330