Your search keyword '"Harres, K."' showing total 2 results

1. Shaping laser accelerated ions for future applications – The LIGHT collaboration

Author

Busold, S., Almomani, A., Bagnoud, V., Barth, W., Bedacht, S., Blažević, A., Boine-Frankenheim, O., Brabetz, C., Burris-Mog, T., Cowan, T. E., Deppert, O., Droba, M., Eickhoff, H., Eisenbarth, U., Harres, K., Hoffmeister, G., Hofmann, I., Jaeckel, O., Jaeger, R., Joost, M., Kraft, S., Kroll, F., Kaluza, M., Kester, O., Lecz, Z., Merz, T., Nürnberg, F., Al-Omari, H., Orzhekhovskaya, A., Paulus, G., Polz, J., Ratzinger, U., Roth, M., Schaumann, G., Schmidt, P., Schramm, U., Schreiber, G., Schumacher, D., Stoehlker, T., Tauschwitz, A., Vinzenz, W., Wagner, F., Yaramyshev, S., and Zielbauer, B.

Subjects

Physics::Plasma Physics, Acceleration, Physics::Accelerator Physics, Laser, Proton, Ion

Abstract

The generation of intense ion beams from high-intensity laser-generated plasmas has been the focus of research for the last decade. In the LIGHT collaboration the expertise of heavy ion accelerator scientists and laser and plasma physicists has been combined to investigate the prospect of merging these ion beams with conventional accelerator technology and exploring the possibilities of future applications. We report about the goals and first results of the LIGHT collaboration to generate, handle and transport laser driven ion beams. This effort constitutes an important step in research for next generation accelerator technologies.

Published

2014

2. Prospects For and Progress Towards Laser-Driven Particle Therapy Accelerators

Author

Cowan, T. E., Schramm, U., Burris-Mog, T., Fiedler, F., Kraft, S. D., Zeil, K., Baumann, M., Bussmann, M., Enghardt, W., Kirk A. Flippo, Gaillard, S., Harres, K., Herrmannsdoerfer, T., Kluge, T., Nurnberg, F., Pawelke, J., Roth, M., Schmidt, B., Sobiella, M., and Sauerbrey, R.

Subjects

compact, dosimetry, cancer, acceleration, radiotherapy, plasma, beamline, proton, laser

Abstract

Recent advances in laser-ion acceleration have motivated research towards laser-driven compact accelerators for medical therapy. Realizing laser-ion acceleration for medical therapy will require adapting the medical requirements to the foreseeable laser constraints, as well as advances in laser-acceleration physics, beam manipulation and delivery, real-time dosimetry, treatment planning and translational research into a clinical setting.