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$^{12}$C nuclear reaction measurements for hadrontherapy.

Hadrontherapy treatments require a very high precision on the dose deposition ( 2.5% and 1-2mm) in order to keep the benefits of the precise ions’ ballistic. The largest uncertainty on the physical dose deposition is due to ion fragmentation. Up to now, the simulation codes are not able to reproduce...

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Detalles Bibliográficos
Autores principales: B. Braunn, B, M. Labalme, M, G. Ban, G, J.Colin, J, D. Cussol, D, J.M. Fontbonne, J M, F.R.. Lecolley, F R, C. Pautard, C, Haas, F, Lebhertz, D, Rousseau, M, Stuttge, L, Chevallier, M, Dauvergne, D, Le Foulher, F, Ray, C, Testa, E, Testa, M, Salsac, M D
Lenguaje:eng
Publicado: 2010
Materias:
XX
Acceso en línea:http://cds.cern.ch/record/1238369
Descripción
Sumario:Hadrontherapy treatments require a very high precision on the dose deposition ( 2.5% and 1-2mm) in order to keep the benefits of the precise ions’ ballistic. The largest uncertainty on the physical dose deposition is due to ion fragmentation. Up to now, the simulation codes are not able to reproduce the fragmentation process with the required precision. To constraint the nuclear models and complete fragmentation cross sections databases; our collaboration has performed an experiment on May 2008 at GANIL with a 95 MeV/u 12C beam. We have measured the fluence, energy and angular distributions of charged fragments and neutrons coming from nuclear reactions of incident 12C on thick water-like PMMA targets. Preliminary comparisons between GEANT4 (G4BinaryLightIonReaction) simulations and experimental data show huge discrepancies.