Your search keyword '"gaseous proton recoil telescope"' showing total 2 results

1. Towards the experimental validation of a small Time-Projection-Chamber for the quasi-absolute measurement of the fission cross section.

Author

Chatel, Carole, Mathieu, Ludovic, Aïche, Mourad, Diakaki, Maria, Noguere, Gilles, and Bouland, Olivier

Subjects

*NEUTRONS, *ELASTIC scattering, *LOW energy electron diffraction, *IONIZATION (Atomic physics), *SILICON

Abstract

To accurately measure neutron-induced fission cross sections, to characterize neutron-beam lines or to make dosimetric investigations, it is necessary to have high accuracy measurements of neutron fluence. It is possible to perform independent and precise neutron flux measurements with respect to the 1H(n,n)p elastic scattering cross section. The use of a silicon detector is recommended from 1 to 70 MeV neutron energy. However, it has been observed that a high electrons background forbids its use below 1 MeV. Hence, a new gaseous proton-recoil telescope is developed and characterized to overcome this limit. It should provide quasi-absolute neutron flux measurements with an accuracy around 3% and is not sensible to gamma and electrons background. It consists in two ionization chambers read by a segmented micromegas technology detection plane. The gas pressure inside is adjustable to the proton range in the detector and therefore to the neutron energy. This detector is described in details below and the newest results of its characterization are presented. A special attention is paid to detection efficiency measurements. [ABSTRACT FROM AUTHOR]

Published

2021

2. Towards the experimental validation of a small Time-Projection-Chamber for the quasi-absolute measurement of the fission cross section

Author

Carole Chatel, L. Mathieu, M. Aiche, Olivier Bouland, Gilles Noguere, and M. Diakaki

Subjects

Physics, Elastic scattering, Time projection chamber, Physics::Instrumentation and Detectors, Fission, QC1-999, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Detector, low energy neutron flux measurements, MicroMegas detector, Neutron temperature, Computational physics, gaseous proton recoil telescope, Neutron flux, Ionization, Nuclear Experiment

Abstract

To accurately measure neutron-induced fission cross sections, to characterize neutron-beam lines or to make dosimetric investigations, it is necessary to have high accuracy measurements of neutron fluence. It is possible to perform independent and precise neutron flux measurements with respect to the 1H(n,n)p elastic scattering cross section. The use of a silicon detector is recommended from 1 to 70 MeV neutron energy. However, it has been observed that a high electrons background forbids its use below 1 MeV. Hence, a new gaseous proton-recoil telescope is developed and characterized to overcome this limit. It should provide quasi-absolute neutron flux measurements with an accuracy around 3% and is not sensible to gamma and electrons background. It consists in two ionization chambers read by a segmented micromegas technology detection plane. The gas pressure inside is adjustable to the proton range in the detector and therefore to the neutron energy. This detector is described in details below and the newest results of its characterization are presented. A special attention is paid to detection efficiency measurements.