All-optical source size and emittance measurements of laser-accelerated electron beams

F C Salgado,F C Salgado,F C Salgado,M Zepf,M Kaluza,D Ullmann,M Kaluza,A Seidel,A Kozan,D Hollatz,D Hollatz,P Hilz,D Hollatz,A Seidel,A Seidel,M Kaluza,D Hollatz,A Sävert,A Seidel,A Sävert,D Hollatz,M Kaluza,A Sävert,P Hilz,D Hollatz,D Seipt,P Hilz,M Zepf,M Zepf,M Zepf,D Hollatz,A Seidel,A Sävert,Y Zhao,D Ullmann,M Zepf,M Kaluza,D Hollatz,A Seidel,A Seidel,M Kaluza,M Kaluza,M Zepf,P Hilz,P Hilz,P Hilz,A Sävert,A Seidel,M Kaluza,D Seipt,A Sävert,D Seipt,Y Zhao,P Hilz,A Kozan,A Sävert,Y Zhao,A Sävert,A Sävert,M Zepf,P Hilz,D Ullmann,D Hollatz,M Kaluza,A Kozan,M Zepf,P Hilz,M Zepf,A Seidel

doi:10.1103/physrevaccelbeams.27.052803

F C Salgado, F C Salgado + Show 67 more

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https://doi.org/10.1103/physrevaccelbeams.27.052803

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Journal: Physical Review Accelerators and Beams	Publication Date: May 20, 2024
License type: CC BY 4.0

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Novel schemes for generating ultralow emittance electron beams have been developed in past years and promise compact particle sources with excellent beam quality suitable for future high-energy physics experiments and free-electron lasers. Recent theoretical work has proposed a laser-based method capable of resolving emittances in the sub 0.1 mm mrad regime by modulating the electron phase space ponderomotively. Here we present the first experimental demonstration of this scheme using a laser wakefield accelerator. The observed emittance and source size are consistent with published values. We also show calculations demonstrating that tight bounds on the upper limit for emittance and source size can be derived from the “laser-grating” method even in the presence of low signal to noise and uncertainty in laser-grating parameters. Published by the American Physical Society 2024

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