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Modeling Zinc Complexes Using Neural Networks

H.-Q. Jin, Kenneth M. Merz

2024Journal of Chemical Information and Modeling13 citationsDOIOpen Access PDF

Abstract

Understanding the energetic landscapes of large molecules is necessary for the study of chemical and biological systems. Recently, deep learning has greatly accelerated the development of models based on quantum chemistry, making it possible to build potential energy surfaces and explore chemical space. However, most of this work has focused on organic molecules due to the simplicity of their electronic structures as well as the availability of data sets. In this work, we build a deep learning architecture to model the energetics of zinc organometallic complexes. To achieve this, we have compiled a configurationally and conformationally diverse data set of zinc complexes using metadynamics to overcome the limitations of traditional sampling methods. In terms of the neural network potentials, our results indicate that for zinc complexes, partial charges play an important role in modeling the long-range interactions with a neural network. Our developed model outperforms semiempirical methods in predicting the relative energy of zinc conformers, yielding a mean absolute error (MAE) of 1.32 kcal/mol with reference to the double-hybrid PWPB95 method.

Topics & Concepts

MetadynamicsChemical spaceZincArtificial neural networkBiological systemComputer scienceMoleculeRange (aeronautics)Conformational isomerismSet (abstract data type)Computational chemistryChemistryArtificial intelligenceMolecular dynamicsMaterials scienceOrganic chemistryProgramming languageBiologyComposite materialBiochemistryDrug discoveryMachine Learning in Materials ScienceComputational Drug Discovery MethodsCrystallography and molecular interactions