Litcius/Paper detail

Analyzing Atomic Interactions in Molecules as Learned by Neural Networks

Malte Esders, Thomas Schnake, Jonas Lederer, Adil Kabylda, Grégoire Montavon, Alexandre Tkatchenko, K. Müller

2025Journal of Chemical Theory and Computation11 citationsDOIOpen Access PDF

Abstract

While machine learning (ML) models have been able to achieve unprecedented accuracies across various prediction tasks in quantum chemistry, it is now apparent that accuracy on a test set alone is not a guarantee for robust chemical modeling such as stable molecular dynamics (MD). To go beyond accuracy, we use explainable artificial intelligence (XAI) techniques to develop a general analysis framework for atomic interactions and apply it to the SchNet and PaiNN neural network models. We compare these interactions with a set of fundamental chemical principles to understand how well the models have learned the underlying physicochemical concepts from the data. We focus on the strength of the interactions for different atomic species, how predictions for intensive and extensive quantum molecular properties are made, and analyze the decay and many-body nature of the interactions with interatomic distance. Models that deviate too far from known physical principles produce unstable MD trajectories, even when they have very high energy and force prediction accuracy. We also suggest further improvements to the ML architectures to better account for the polynomial decay of atomic interactions.

Topics & Concepts

Computer scienceSet (abstract data type)Artificial neural networkQuantumQuantum chemicalArtificial intelligenceMachine learningBiological systemStatistical physicsMoleculePhysicsQuantum mechanicsBiologyProgramming languageMachine Learning in Materials ScienceComputational Drug Discovery MethodsTopic Modeling
Analyzing Atomic Interactions in Molecules as Learned by Neural Networks | Litcius