Your search keyword '"Wesch S"' showing total 3 results

1. Energy-spread preservation and high efficiency in a plasma-wakefield accelerator

Author

Lindstroem, Carl Andreas, Garland, J. M., Schröder, Sarah, Boulton, Lewis, Boyle, G., Chappell, J., D'Arcy, Richard, Gonzalez Caminal, Pau, Knetsch, A., Libov, Vladyslav, Loisch, G., Martinez De La Ossa, A., Niknejadi, P., Põder, K., Schaper, L., Schmidt, Bernhard, Sheeran, B., Wesch, S., Wood, J., and Osterhoff, Jens

Subjects

Physics::Plasma Physics, Physics::Accelerator Physics, ddc:530, QC

Abstract

Physical review letters 126(1), 014801 (1-6) (2021). doi:10.1103/PhysRevLett.126.014801, Energy-efficient plasma-wakefield acceleration of particle bunches with low energy spread is a promising path to realizing compact free-electron lasers and particle colliders. High efficiency and low energy spread can be achieved simultaneously by strong beam loading of plasma wakefields when accelerating bunches with carefully tailored current profiles [M. Tzoufras {et al.}, Phys.Rev.Lett.~101, 145002 (2008)]. We experimentally demonstrate such optimal beam loading in a nonlinear electron-driven plasma accelerator. Bunches with initial energy of 1 GeV were accelerated by 45 MeV with an energy-transfer efficiency of (42±4)% at a gradient of 1.3 GV/m while preserving per-mille energy spreads with full charge coupling, demonstrating wakefield flattening at the few-percent level., Published by APS, College Park, Md.

Published

2021

2. High-resolution sampling of beam-driven plasma wakefields

Author

Schröder, S., Lindstrøm, C. A., Bohlen, S., Boyle, G., D’Arcy, R., Diederichs, S., Garland, M. J., Gonzalez, P., Knetsch, A., Libov, V., Niknejadi, P., Pøder, K., Schaper, L., Schmidt, B., Sheeran, B., Tauscher, G., Wesch, S., Zemella, J., Zeng, M., and Osterhoff, J.

Subjects

accelerator, Science, wake field [plasma], plasma: wake field, Characterization and analytical techniques, longitudinal [electric field], electric field: longitudinal, Article, particle: acceleration, Automatic Keywords, Physics::Plasma Physics, Physics::Accelerator Physics, ddc:500, acceleration [particle], Plasma-based accelerators

Abstract

Nature Communications 11(1), 5984 (1-6) (2020). doi:10.1038/s41467-020-19811-9, Plasma-wakefield accelerators driven by intense particle beams promise to significantly reduce the size of future high-energy facilities. Such applications require particle beams with a well-controlled energy spectrum, which necessitates detailed tailoring of the plasma wakefield. Precise measurements of the effective wakefield structure are therefore essential for optimising the acceleration process. Here we propose and demonstrate such a measurement technique that enables femtosecond-level (15 fs) sampling of longitudinal electric fields of order gigavolts-per-meter (0.8 GV m⁻¹). This method—based on energy collimation of the incoming bunch—made it possible to investigate the effect of beam and plasma parameters on the beam-loaded longitudinally integrated plasma wakefield, showing good agreement with particle-in-cell simulations. These results open the door to high-quality operation of future plasma accelerators through precise control of the acceleration process., Published by Nature Publishing Group UK, [London]

Published

2020

3. Controlled Density-Downramp Injection in a Beam-Driven Plasma Wakefield Accelerator

Author

Knetsch, A., Sheeran, Bridget, Boulton, Lewis, Niknejadi, P., Põder, Kristjan, Schaper, L., Zeng, M., Bohlen, Simon, Boyle, G., Brümmer, Theresa, Chappell, James, D'Arcy, R., Diederichs, Severin, Foster, B., Garland, M. J., Gonzalez Caminal, P., Hidding, B., Libov, Vladislav, Lindstroem, Carl Andreas, Martinez de la Ossa, Alberto, Meisel, M., Parikh, T., Schröder, Sarah, Tauscher, G., Wesch, S., Winkler, P., Wood, J., Osterhoff, J., and Schmidt, Bernhard

Subjects

Physics::Instrumentation and Detectors, Physics::Plasma Physics, Physics::Accelerator Physics, 7. Clean energy

Abstract

This paper describes the utilization of beam-driven plasma wakefield acceleration to implement a high-quality plasma cathode via density-downramp injection in a short injector stage at the FLASHForward facility at DESY. Electron beams with charge of up to 105 pC and energy spread of a few percent were accelerated by a tunable effective accelerating field of up to 2.7 GV/m. The plasma cathode was operated drift-free with very high injection efficiency. Sources of jitter, the emittance and divergence of the resulting beam were investigated and modeled, as were strategies for performance improvements that would further increase the wide-ranging applications for a plasma cathode with the demonstrated operational stability