Litcius/Paper detail

A Hybrid Machine Learning Approach for Structure Stability Prediction in Molecular Co-crystal Screenings

Simon Wengert, Gábor Cśanyi, Karsten Reuter, Johannes T. Margraf

2022Journal of Chemical Theory and Computation39 citationsDOIOpen Access PDF

Abstract

prediction of co-crystal structures represents a daunting task, however, as they span a vast search space and usually feature large unit cells. This requires theoretical models that are accurate and fast to evaluate, a combination that can in principle be accomplished by modern machine-learned (ML) potentials trained on first-principles data. Crucially, these ML potentials need to account for the description of long-range interactions, which are essential for the stability and structure of molecular crystals. In this contribution, we present a strategy for developing Δ-ML potentials for co-crystals, which use a physical baseline model to describe long-range interactions. The applicability of this approach is demonstrated for co-crystals of variable composition consisting of an active pharmaceutical ingredient and various co-formers. We find that the Δ-ML approach offers a strong and consistent improvement over the density functional tight binding baseline. Importantly, this even holds true when extrapolating beyond the scope of the training set, for instance in molecular dynamics simulations under ambient conditions.

Topics & Concepts

Crystal structure predictionStability (learning theory)Computer scienceSupramolecular chemistryChemical spaceSet (abstract data type)Task (project management)Molecular dynamicsRange (aeronautics)Crystal (programming language)Artificial intelligenceBiological systemMachine learningChemical physicsMaterials scienceCrystal structureChemistryComputational chemistryCrystallographyDrug discoveryManagementBiochemistryComposite materialBiologyEconomicsProgramming languageMachine Learning in Materials ScienceCrystallography and molecular interactionsComputational Drug Discovery Methods