The distribution of the ionization pulse amplitudes in ionization fission chamber due to the fission fragments spread in terms of their charge, mass, and energy
Keywords:
fission chamber, pulse mode, amplitude distribution, trajectory, fission fragmentsAbstract
In the present paper, the distribution of the ionization pulse amplitudes in a fission chamber (FC) due to the spread of fission fragments in terms of their charge, mass and energy is considered for different neutron flux spectra. The estimates are implemented by means of the programs: (i) GEF describing the nuclear fission processes and (ii) SRIM used to calculate the energy losses of ions in the matter. The obtained results demonstrate that the empirical distribution function of ionization pulse amplitudes has two maxima, being practically independent of the types of a neutron flux spectrum. This result allows us to conclude that neutrons with different spectra may be used to calibrate a pulsed mode FC. This should greatly simplify the calibration process for such cameras.
References
- Malyshev E. K., Zasadych Yu. B., Stabrovsky S. A. Gas-Discharge detectors for the nuclear reactors control. Мoscow, 1991 (in Russ.).
- Le Thi Dieu Hien, Kuten S. А., Khrutchinsky А. А. Initial ionization distribution in active volume of ionization chamber. Proc. Natl. Acad. Sci. Belarus. Ser. phys.-math. sci. 2017. No. 1. P. 111–119 (in Russ.).
- Filliatrea P., Jammes C., Geslot B., et al. A Monte Carlo simulation of the fission chambers neutron-induced pulse shape using the GARFIELD suite. Nucl. Instr. Meth. A. 2012. Vol. 678. P. 139–147.
- Tsoulfanidis N. Measurement and detection of radiation, second edition. Washington, 1995.
- Elmer E. Lewis. Fundamentals of Nuclear Reactor Physics. New York, 2008.
- Klimov A. N. Nuclear physics and nuclear reactors. Moscow, 1985 (in Russ.).
- Bartolomey G. G., Baibakov V. D., Alhutov M. S., et al. Basic theory and methods for calculating nuclear power reactors. Moscow, 1982 (in Russ.).
- Volkov S. V., Kirilkin N. S. Neutron detectors for software control channels of neutron flux. Prib. sist. Upravlenie, kontrolʼ, diagn. 2006. No. 10. P. 42–50 (in Russ.).
- Kalashnikova V. I., Kozodaev M. S. Detectors of elementary particles. Moscow, 1966 (in Russ.).
- Schmidt K.-H., Jurado B., Amouroux Ch. General description of fission observables, GEF model. JEFF Report 24, NEA Data Bank of the OECD. 2014.
- Ziegler J. F., Biersack J. P., Littmark U. SRIM – The Stopping and Range of Ions in Solids. New York, 1996.
- Chabod S., Fioni G., Letourneau A., et al. Modeling of Fission Chambers in Current Mode – Analytical Approach. Nucl. Instr. Meth. A. 2006. Vol. 566. P. 633–653.
- MCNP – A General Monte Carlo N-Particle Transport Code, Version 4B. Los Alamos, 1997.
- Poujade O., Lebrun A. Modeling of the saturation current of a fission chamber taking into account the distorsion of electric field due to space charge effects. Nucl. Instr. Meth. A. 1999. Vol. 433. P. 673.
- Dmitriev A. B., Malyshev E. K. Neutron ionization chambers for reactor equipment. Moscow, 1975 (in Russ.).
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