Laser accelerated proton beams have a considerable potential for various applications including oncological therapy. However, the most consolidated target normal sheath acceleration regime based on irradiation of solid targets provides an exponential energy spectrum with a significant divergence. The low count number at the cutoff energy seriously limits at present its possible use. One realistic scenario for the near future is offered by hybrid schemes. The use of transport lines for collimation and energy selection has been considered. We present here a scheme based on a high field pulsed solenoid and collimators which allows one to select a beam suitable for injection at 30 MeV into a compact linac in order to double its energy while preserving a significant intensity. The results are based on a fully 3D simulation starting from laser acceleration.
S. Sinigardi, G. Turchetti, P. Londrillo, F. Rossi, D. Giove, C. De Martinis, et al. (2013). Transport and energy selection of laser generated protons for postacceleration with a compact linac. PHYSICAL REVIEW SPECIAL TOPICS. ACCELERATORS AND BEAMS, 16(3), 031301-1-031301-13 [10.1103/PhysRevSTAB.16.031301].
Transport and energy selection of laser generated protons for postacceleration with a compact linac
SINIGARDI, STEFANO;TURCHETTI, GIORGIO;SUMINI, MARCO
2013
Abstract
Laser accelerated proton beams have a considerable potential for various applications including oncological therapy. However, the most consolidated target normal sheath acceleration regime based on irradiation of solid targets provides an exponential energy spectrum with a significant divergence. The low count number at the cutoff energy seriously limits at present its possible use. One realistic scenario for the near future is offered by hybrid schemes. The use of transport lines for collimation and energy selection has been considered. We present here a scheme based on a high field pulsed solenoid and collimators which allows one to select a beam suitable for injection at 30 MeV into a compact linac in order to double its energy while preserving a significant intensity. The results are based on a fully 3D simulation starting from laser acceleration.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.