Pulse shape discrimination for α event rejection in BEGe-type high-purity germanium detectors

Abstract

High-purity germanium detectors are widely used in rare-event searches due to their excellent energy resolution and extremely high intrinsic (radio)purity. In experiments searching for neutrinoless double beta decay in 76Ge such as LEGEND, pulse shape discrimination is required to suppress multi-site γ events. In this work, we investigate whether pulse shape discrimination classifiers trained exclusively on γ ray data can be used to identify and reject α events, without the need for dedicated α training. In detectors such as LEGEND, the total number of registered α events over the experiment lifetime is expected to be insufficient to train dedicated classifiers, while still contributing to the background. Two approaches based on machine learning are studied: a multilayer perceptron and a projective likelihood classifier. The p+ surface of a point-contact semi-planar germanium detector was exposed to 209Po and 210Po sources deposited on a thin gold foil. Two measurement campaigns were performed, yielding 1.36×105 and 1.87×106 α events, respectively. Both classification methods achieve efficient separation of single-site and multi-site γ events while strongly reducing the α component. The multilayer perceptron provides the best overall performance, with a signal-like event survival greater than 80%, a background-like event survival below 20%, and an α-rejection factor exceeding 2.71×104. These results demonstrate that robust pulse shape discrimination for high-purity germanium detectors can be achieved using training information derived solely from γ events, providing a promising strategy for next-generation neutrinoless double beta decay searches.