Muon Track Reconstruction in a Segmented Bolometric Array Using Multi-Objective Optimization

TL;DR

This paper introduces a multi-objective optimization algorithm to enhance track reconstruction in segmented bolometric detectors, enabling better identification of exotic particles like monopoles and LIPs by analyzing energy depositions and path lengths.

Contribution

The paper presents a novel multi-objective optimization approach for reconstructing particle tracks in segmented detectors, improving spatial resolution and particle identification capabilities.

Findings

Reconstruction precision evaluated with Monte Carlo data.

Algorithm applicable to various segmented calorimeter detectors.

Enhanced detection of particles with abnormal stopping power.

Abstract

Recent advances in segmented solid-state detector arrays for rare-event searches have allowed the technology to approach the ton-scale in detector mass and the scale of meters in size. Often focused around searches for neutrinoless double-beta decay or direct dark matter detection, such experiments also have the capability to search for exotic particles that leave track-like signatures across their volume. However, the segmented nature of such detector arrays often sets the spatial resolution and makes the problem of reconstructing track-like paths non-trivial. In this paper, we present an algorithm that improves reconstruction of track-like events in segmented detectors using multi-objective optimization - a computational technique that optimizes more than one cost function at a time without specifying a quantitative weighting between them. Such a technique allows the reconstruction of tracks through a detector and the determination of path-lengths through individual elements. When combined with the reconstructed energy depositions in each element this allows for a calculation of the stopping power of track-like particles and opens the door to searches for particles with abnormal stopping power like monopoles or lightly-ionizing particles (LIPs). Results are presented which evaluate the precision of the reconstruction tools as they currently stand against Monte Carlo generated data. The algorithm is presented in the context of the CUORE experiment, but has applications to other segmented calorimeter detectors.