Characterization of Fissile Assemblies Using Low-Efficiency Detection Systems

Abstract

We have investigated the possibility that the amount, chemical form, multiplication, and shape of the fissile material in an assembly can be passively assayed using scintillator detection systems by only measuring the fast neutron pulse height distribution and distribution of time intervals $\Delta \text{t}$ between fast neutrons. We have previously demonstrated that the alpha ratio can be obtained from the observed pulse height distribution for fast neutrons. In this paper, we report that when the distribution of time intervals is plotted as a function of log $\Delta t$ , the position of the correlated neutron peak is nearly independent of detector efficiency and determines the internal relaxation rate for fast neutrons. If this information is combined with knowledge of the alpha ratio, then the position of the minimum between the correlated and uncorrelated peaks can be used to rapidly estimate the mass, multiplication, and shape of fissile material. This method does not require a priori knowledge of either the efficiency for neutron detection or the alpha ratio. Although our method neglects three-neutron correlations, we have used previously obtained experimental data for metallic and oxide forms of Pu to demonstrate that our method yields good estimates for multiplications as large as 2, and that the only constraint on detector efficiency/observation time is that a peak in the interval time distribution due to correlated neutrons is visible.