English

Generating stable molecules using imitation and reinforcement learning

Chemical Physics 2021-07-13 v1 Machine Learning

Abstract

Chemical space is routinely explored by machine learning methods to discover interesting molecules, before time-consuming experimental synthesizing is attempted. However, these methods often rely on a graph representation, ignoring 3D information necessary for determining the stability of the molecules. We propose a reinforcement learning approach for generating molecules in cartesian coordinates allowing for quantum chemical prediction of the stability. To improve sample-efficiency we learn basic chemical rules from imitation learning on the GDB-11 database to create an initial model applicable for all stoichiometries. We then deploy multiple copies of the model conditioned on a specific stoichiometry in a reinforcement learning setting. The models correctly identify low energy molecules in the database and produce novel isomers not found in the training set. Finally, we apply the model to larger molecules to show how reinforcement learning further refines the imitation learning model in domains far from the training data.

Keywords

Cite

@article{arxiv.2107.05007,
  title  = {Generating stable molecules using imitation and reinforcement learning},
  author = {Søren Ager Meldgaard and Jonas Köhler and Henrik Lund Mortensen and Mads-Peter V. Christiansen and Frank Noé and Bjørk Hammer},
  journal= {arXiv preprint arXiv:2107.05007},
  year   = {2021}
}
R2 v1 2026-06-24T04:04:40.390Z