17 research outputs found
Analytical model for a monolithic silicon telescope - Response function of the E stage
A monolithic silicon telescope coupled to a polyethylene radiator was studied and tested as a neutron
spectrometer. The detector consists of a DE and an E stage detector, about 1.9 and 500 mm in thickness,
respectively. The neutron spectra were derived from the measurement of the energy deposited in the E
stage by recoil-protons generated in the radiator. The detectable energy range of the present detection
system is about 0.350–8 MeV. In order to optimize the reconstruction of the impinging neutron spectra,
an analytical model of the response functions of the detection system to mono-energetic neutrons was
developed and implemented in an unfolding procedure. The model is based on the kinematics of neutron
elastic scattering on hydrogen and takes into account the actual geometrical structure of the silicon
telescope. The calculated response functions were compared with the results of Monte Carlo simulations
(by using the FLUKA code) and those obtained by an experimental characterization
Double-differential spectra of secondary particles from hadrons on tissue equivalent targets
Double-differential spectra generated by ions on tissue equivalent targets were calculated with the FLUKA code. Seven different
species of ion beams were simulated, impinging onto an ICRU tissue equivalent target representing the chest of a patient
under treatment. The following ion beams were investigated at an energy level capable of penetrating ICRU tissue up to a
26.2 cm depth: H, He, Li, B, C, N and O at 200.0, 202.0, 234.3, 329.5, 390.7, 430.5 and 468.0 MeV u21, respectively. The
double-differential spectra of secondary neutrons, protons, photons, positive and negative pions, electrons and positrons were
scored over the entire solid angle. Curve-fitting of the calculated data is also given