A Note on Neutron Capture Correlation Signals, Backgrounds, and Efficiencies

TL;DR

This paper analyzes neutron capture timing signals across various detection applications, highlighting how background signals and detector design influence correlation timing distributions and detection efficiencies.

Contribution

It provides a detailed explanation of neutron capture timing characteristics, referencing simulations and data, to improve background discrimination and accuracy in detection efficiency estimation.

Findings

Timing distribution depends on neutron capture agent and geometry

Features identified can aid in background discrimination

Careful accounting of timing features improves efficiency estimates

Abstract

A wide variety of detection applications exploit the timing correlations that result from the slowing and eventual capture of neutrons. These include capture-gated neutron spectrometry, multiple neutron counting for fissile material detection and identification, and antineutrino detection. There are several distinct processes that result in correlated signals in these applications. Depending on the application, one class of correlated events can be a background that is difficult to distinguish from the class that is of interest. Furthermore, the correlation timing distribution depends on the neutron capture agent and detector geometry. Here, we explain the important characteristics of the neutron capture timing distribution, making reference to simulations and data from a number of detectors currently in use or under development. We point out several features that may assist in background discrimination, and that must be carefully accounted for if accurate detection efficiencies are to be quoted.