Scintillation detector efficiencies for neutrons in the energy region above 20 MeV
Abstract
The computer program SCINFUL (for SCINtillator FUL1 response) is a program designed to provide a calculated complete pulse-height response anticipated for neutrons being detected by either an NE-213 (liquid) scintillator or an NE-110 (solid) scintillator in the shape of a right circular cylinder. The point neutron source may be placed at any location with respect to the detector, even inside of it. The neutron source may be monoenergetic, or Maxwellian distributed, or distributed between chosen lower and upper bounds. The calculational method uses Monte Carlo techniques, and it is relativistically correct. Extensive comparisons with a variety of experimental data were made. There is generally overall good agreement (less than 10 pct. differences) of results for SCINFUL calculations with measured integral detector efficiencies for the design incident neutron energy range of 0.1 to 80 MeV. Calculations of differential detector responses, i.e., yield versus response pulse height, are generally within about 5 pct. on the average for incident neutron energies between 16 and 50 MeV and for the upper 70 pct. of the response pulse height. For incident neutron energies between 50 and 80 MeV, the calculated shape of the response agrees with measurements, but the calculations tend to underpredict the absolute values of the measured responses. Extension of the program to compute responses for incident neutron energies greater than 80 MeV will require new experimental data on neutron interactions with carbon.
- Publication:
-
Presented at the Specialists' Meeting on Neutron Cross Section Standards for the Energy Region Above 20 MeV
- Pub Date:
- 1991
- Bibcode:
- 1991ncss.meet...21D
- Keywords:
-
- Computer Programs;
- Energy Levels;
- Neutron Sources;
- Neutrons;
- Scintillation Counters;
- Circular Cylinders;
- Detection;
- Efficiency;
- Monte Carlo Method;
- Radiation Detectors;
- Scattering;
- Scintillation;
- Atomic and Molecular Physics