1.Ludwig-Maximilian-Universität München, Am Coulombwall 1, 85748 Garching, Germany
2.Max Planck Institut für Quantenoptik, Hans-Kopfermann-Strasse 1, Garching 85748, Germany
Andreas Döpp (a.doepp@lmu.de)
Published:31 July 2024,
Published Online:12 June 2024,
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Döpp, A. Snapshot imaging of ultrashort electron bunches. Light: Science & Applications, 13, 1226-1228 (2024).
Döpp, A. Snapshot imaging of ultrashort electron bunches. Light: Science & Applications, 13, 1226-1228 (2024). DOI: 10.1038/s41377-024-01489-z.
New measurements combine spatial and temporal information from optical transition radiation to estimate the three-dimensional structure of electron bunches from a laser wakefield accelerator.
Esarey, E., Schroeder, C. B.&Leemans, W. P. Physics of laser-driven plasma-based electron accelerators.Rev. Mod. Phys.81, 1229–1285 (2009)..
Malka, V. Laser plasma accelerators.Phys. Plasmas19, 055501 (2012)..
Gilljohann, M. F. et al. Direct observation of plasma waves and dynamics induced by laser-accelerated electron beams.Phys. Rev. X9, 011046 (2019)..
Götzfried, J. et al. Physics of high-charge electron beams in laser-plasma wakefields.Phys. Rev. X10, 041015 (2020)..
Kirchen, M. et al. Optimal beam loading in a laser-plasma accelerator.Phys. Rev. Lett.126, 174801 (2021)..
Albert, F.&Thomas, A. G. R. Applications of laser Wakefield accelerator-based light sources.Plasma Phys. Controlled Fusion58, 103001 (2016)..
Downer, M. C. et al. Diagnostics for plasma-based electron accelerators.Rev. Mod. Phys.90, 035002 (2018)..
Casalbuoni, S. et al. Numerical studies on the electro-optic detection of femtosecond electron bunches.Phys. Rev. Spec. Top. - Accelerators Beams11, 072802 (2008)..
Debus, A. D. et al. Electron bunch length measurements from laser-accelerated electrons using single-shot THz time-domain interferometry.Phys. Rev. Lett.104, 084802 (2010)..
Lundh, O. et al. Few femtosecond, few kiloampere electron bunch produced by a laser–plasma accelerator.Nat. Phys.7, 219–222 (2011)..
Heigoldt, M. et al. Temporal evolution of longitudinal bunch profile in a laser Wakefield accelerator.Phys. Rev. Spec. Top. - Accelerators Beams18, 121302 (2015)..
Zarini, O. et al. Multioctave high-dynamic range optical spectrometer for single-pulse, longitudinal characterization of ultrashort electron bunches.Phys. Rev. Accelerators Beams25, 012801 (2022)..
Huang, K. et al. Electro-optic 3D snapshot of a laser Wakefield accelerated kilo-ampere electron bunch.Light Sci. Appl.13, 84 (2024)..
Huang, K. et al. Single-shot electro-optic sampling on the temporal structure of laser Wakefield accelerated electrons.Crystals10, 640 (2020)..
Huang, K. et al. Numerical study on femtosecond electro-optical spatial decoding of transition radiation from laser Wakefield accelerated electron bunches.Phys. Rev. Accelerators Beams26, 112801 (2023)..
Döpp, A. et al. Data-driven science and machine learning methods in laser–plasma physics.High Power Laser Sci. Eng.11, e55 (2023)..
Tang, H. C. et al. Single-shot compressed optical field topography.Light Sci. Appl.11, 244 (2022)..
Howard, S. et al. Hyperspectral compressive wavefront sensing.High Power Laser Sci. Eng.11, e32 (2023)..
Wan, Y. et al. Femtosecond electron microscopy of relativistic electron bunches.Light Sci. Appl.12, 116 (2023)..
Wan, Y. et al. Real-time visualization of the laser-plasma Wakefield dynamics.Sci. Adv.10, eadj3595 (2024)..
Li, F. et al. Ultrabright electron bunch injection in a plasma Wakefield driven by a superluminal flying focus electron beam.Phys. Rev. Lett.128, 174803 (2022)..
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