Space-Dependent Calculation of the Multiplicity Moments for Shells With the Inclusion of Scattering
Journal article, 2023

In recent work, we extended the methodology of multiplicity counting in nuclear safeguards by elaborating the one-speed stochastic transport theory of the calculation of the so-called multiplicity moments, i.e., the factorial moments of the number of neutrons emitted from a fissile item, following a source event from an internal neutron source [spontaneous fission and ((Formula presented.)) reactions]. Calculations were made for solid spheres and cylinders, with the source being homogeneously distributed within the item. Recent measurements of the Rocky Flats Shells during the Measurement of Uranium Subcritical and Critical (MUSIC) campaign conducted by Los Alamos National Laboratory and assisted by the University of Michigan inspired us to extend the model to spherical shell geometry with a point source in the middle of the central cavity. Comparison of the calculated results with the experimental ones indicated that accounting for fission as the only neutron reaction (the standard procedure in the point model, adapted also in our work so far) was not sufficient for reaching good agreement with measurements. The model was therefore extended to include elastic scattering into the one-speed formalism, whereas the effect of inelastic scattering was accounted for in an empirical way. After these extensions, good agreement was found between the calculated and the measured values. The paper describes the extension of the theory and provides concrete quantitative results.

space-dependent model

elastic scattering

Multiplicity moments

point source

inelastic scattering

shell items

Rocky Flats Shells

Author

Imre Pazsit

Chalmers, Physics, Subatomic, High Energy and Plasma Physics

Victor Dykin

Chalmers, Physics, Subatomic and Plasma Physics

Flynn Darby

University of Michigan

Nuclear Science and Engineering

0029-5639 (ISSN) 1943748x (eISSN)

Vol. 197 8 2030-2046

Subject Categories

Accelerator Physics and Instrumentation

Subatomic Physics

Theoretical Chemistry

DOI

10.1080/00295639.2023.2178249

More information

Latest update

3/7/2024 9