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Main Authors: Voetberg, Margaret, Grizzi, Vitor F., Cerati, Giuseppe, Meidani, Hadi, Hewes, V
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.10676
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author Voetberg, Margaret
Grizzi, Vitor F.
Cerati, Giuseppe
Meidani, Hadi
Hewes, V
author_facet Voetberg, Margaret
Grizzi, Vitor F.
Cerati, Giuseppe
Meidani, Hadi
Hewes, V
contents With the growing popularity of artificial intelligence used for scientific applications, the ability of attribute a result to a reasoning process from the network is in high demand for robust scientific generalizations to hold. In this work we aim to motivate the need for and demonstrate the use of post-hoc explainability methods when applied to AI methods used in scientific applications. To this end, we introduce explainability add-ons to the existing graph neural network (GNN) for neutrino tagging, NuGraph2. The explanations take the form of a suite of techniques examining the output of the network (node classifications) and the edge connections between them, and probing of the latent space using novel general-purpose tools applied to this network. We show how none of these methods are singularly sufficient to show network "understanding", but together can give insights into the processes used in classification. While these methods are tested on the NuGraph2 application, they can be applied to a broad range of networks, not limited to GNNs. The code for this work is publicly available on GitHub at https://github.com/voetberg/XNuGraph.
format Preprint
id arxiv_https___arxiv_org_abs_2509_10676
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle NuGraph2 with Explainability: Post-hoc Explanations for Geometric Neural Network Predictions
Voetberg, Margaret
Grizzi, Vitor F.
Cerati, Giuseppe
Meidani, Hadi
Hewes, V
High Energy Physics - Experiment
With the growing popularity of artificial intelligence used for scientific applications, the ability of attribute a result to a reasoning process from the network is in high demand for robust scientific generalizations to hold. In this work we aim to motivate the need for and demonstrate the use of post-hoc explainability methods when applied to AI methods used in scientific applications. To this end, we introduce explainability add-ons to the existing graph neural network (GNN) for neutrino tagging, NuGraph2. The explanations take the form of a suite of techniques examining the output of the network (node classifications) and the edge connections between them, and probing of the latent space using novel general-purpose tools applied to this network. We show how none of these methods are singularly sufficient to show network "understanding", but together can give insights into the processes used in classification. While these methods are tested on the NuGraph2 application, they can be applied to a broad range of networks, not limited to GNNs. The code for this work is publicly available on GitHub at https://github.com/voetberg/XNuGraph.
title NuGraph2 with Explainability: Post-hoc Explanations for Geometric Neural Network Predictions
topic High Energy Physics - Experiment
url https://arxiv.org/abs/2509.10676