Your search keyword '"Panofski, E."' showing total 2 results

1. Commissioning results and electron beam characterization at the S-band photoinjector at SINBAD-ARES

Author

Panofski, E., Assmann, R. W., Burkart, F., Dorda, U., Genovese, L., Jafarinia, F., Jaster-Merz, S. M., Kellermeier, M., Kuropka, W., Lemery, F., Marchetti, B., Marx, D., Mayet, F., Vinatier, T., and Yamin, S.

Subjects

Physics - Accelerator Physics

Abstract

Over the last years, the generation and acceleration of ultra-short, high quality electron beams has attracted more and more interest in accelerator science. Electron bunches with these properties are necessary to operate and test novel diagnostics and advanced high gradient accelerating schemes such as plasma accelerators or dielectric laser accelerators. Furthermore, several medical and industrial applications require high-brightness electron beams. The dedicated R&D facility ARES at DESY will provide such probe beams in the upcoming years. After the setup of the normal-conducting RF photoinjector and linear accelerating structures, ARES successfully started the beam commissioning of the RF gun. This paper gives an overview of the ARES photoinjector setup and summarizes the results of the gun commissioning process. The quality of the first generated electron beams is characterized in terms of charge, momentum, momentum spread and beam size. Additionally, the dependencies of the beam parameters on RF settings are investigated. All measurement results of the characterized beams fulfill the requirements to operate the ARES linac with this RF photoinjector.

Published

2021

2. Developing a 50 MeV LPA-based Injector at ATHENA for a Compact Storage Ring

Author

Panofski, E., Braun, C., Dirkwinkel, J., Hübner, L., Hülsenbusch, T., Maier, A., Messner, P., Osterhoff, J., Palmer, G., Parikh, T., Walker, A., Winkler, P., Eichner, T., Jeppe, L., Jalas, S., Kirchen, M., Schnepp, M., Trunk, M., Werle, C., Bründermann, E., Härer, B., Müller, A. -S., Widmann, C., Kaluza, M. C., and Sävert, A.

Subjects

Physics - Accelerator Physics

Abstract

The laser-driven generation of relativistic electron beams in plasma and their acceleration to high energies with GV/m-gradients has been successfully demonstrated. Now, it is time to focus on the application of laser-plasma accelerated (LPA) beams. The "Accelerator Technology HElmholtz iNfrAstructure" (ATHENA) of the Helmholtz Association fosters innovative particle accelerators and high-power laser technology. As part of the ATHENAe pillar several different applications driven by LPAs are to be developed, such as a compact FEL, medical imaging and the first realization of LPA-beam injection into a storage ring. The latter endeavour is conducted in close collaboration between Deutsches Elektronen-Synchrotron (DESY), Karlsruhe Institute of Technology (KIT) and Helmholtz Institute Jena (HIJ). In the cSTART project at KIT, a compact storage ring optimized for short bunches and suitable to accept LPA-based electron bunches is in preparation. In this conference contribution we will introduce the 50 MeV LPA-based injector and give an overview about the project goals. The key parameters of the plasma injector will be presented. Finally, the current status of the project will be summarized.

Published

2021