Graph neural network for 3D classification of ambiguities and optical crosstalk in scintillator-based neutrino detectors

• Published in: arXiv.org
• Main Authors: Alonso-Monsalve, Saúl, Douqa, Dana, Jesús-Valls, César, Lux, Thorsten, Pina-Otey, Sebastian, Sánchez, Federico, Sgalaberna, Davide, Whitehead, Leigh H
• Format: Paper Journal Article
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 04.02.2021
• Subjects: Algorithms; Classification; Crosstalk; Experiments; Graph neural networks; Machine learning; Neural networks; Neutrinos; Particle physics; Particle tracking; Physics - Data Analysis, Statistics and Probability; Physics - High Energy Physics - Experiment; Physics - Instrumentation and Detectors; Radiation counters; Reconstruction; Scintillation counters; Sensors; Three dimensional flow
• ISSN: 2331-8422
• DOI: 10.48550/arxiv.2009.00688

Deep learning tools are being used extensively in high energy physics and are becoming central in the reconstruction of neutrino interactions in particle detectors. In this work, we report on the performance of a graph neural network in assisting with particle flow event reconstruction. The three-dimensional reconstruction of particle tracks produced in neutrino interactions can be subject to ambiguities due to high multiplicity signatures in the detector or leakage of signal between neighboring active detector volumes. Graph neural networks potentially have the capability of identifying all these features to boost the reconstruction performance. As an example case study, we tested a graph neural network, inspired by the GraphSAGE algorithm, on a novel 3D-granular plastic-scintillator detector, that will be used to upgrade the near detector of the T2K experiment. The developed neural network has been trained and tested on diverse neutrino interaction samples, showing very promising results: the classification of particle track voxels produced in the detector can be done with efficiencies and purities of 94-96% per event and most of the ambiguities can be identified and rejected, while being robust against systematic effects.