Related papers: Improving Molecular Modeling with Geometric GNNs: an Empirical Study

Improving Molecular Modeling with Geometric GNNs: an Empirical Study

URL: http://arxiv.org/abs/2407.08313v1
Date: Thu, 11 Jul 2024 09:04:12 GMT
Title: Improving Molecular Modeling with Geometric GNNs: an Empirical Study
Authors: Ali Ramlaoui, Théo Saulus, Basile Terver, Victor Schmidt, David Rolnick, Fragkiskos D. Malliaros, Alexandre Duval,
Abstract summary: This paper focuses on the impact of different canonicalization methods, (2) graph creation strategies, and (3) auxiliary tasks, on performance, scalability and symmetry enforcement. Our findings and insights aim to guide researchers in selecting optimal modeling components for molecular modeling tasks.
Score: 56.52346265722167
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Rapid advancements in machine learning (ML) are transforming materials science by significantly speeding up material property calculations. However, the proliferation of ML approaches has made it challenging for scientists to keep up with the most promising techniques. This paper presents an empirical study on Geometric Graph Neural Networks for 3D atomic systems, focusing on the impact of different (1) canonicalization methods, (2) graph creation strategies, and (3) auxiliary tasks, on performance, scalability and symmetry enforcement. Our findings and insights aim to guide researchers in selecting optimal modeling components for molecular modeling tasks.

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