Litcius/Paper detail

Accurate and Interpretable Dipole Interaction Model-Based Machine Learning for Molecular Polarizability

Chaoqiang Feng, Jin Xi, Yaolong Zhang, Bin Jiang, Yong Zhou

2023Journal of Chemical Theory and Computation22 citationsDOI

Abstract

Polarizabilities play significant roles in describing dispersive and inductive interactions of the atom and molecular systems. However, an accurate prediction of molecular polarizabilities from first principles is computationally prohibitive. Although physical models or statistical machine learning models have been proposed, either a lack of accurate description of local chemical environments or demanding a large number of samples for training has limited their practical applications. In this study, we combine a physically inspired dipole interaction model and an accurate neural network method for predicting the polarizability tensors of molecules. With the local chemical environment precisely described and the requirement of rotational covariance naturally fulfilled, this hybrid model is proven to give an accurate molecular polarizability prediction, essentially reducing the number of training samples. The atomic polarizabilities are physically interpretable and transferable to larger molecules unseen in the training set. This promising method may find its wide range of applications, such as spectroscopic simulations and the construction of polarizable force fields.

Topics & Concepts

PolarizabilityDipoleComputer scienceMachine learningArtificial neural networkRange (aeronautics)Set (abstract data type)Atom (system on chip)Artificial intelligenceTraining setMoleculeMolecular dynamicsStatistical physicsComputational chemistryPhysicsChemistryQuantum mechanicsMaterials scienceProgramming languageEmbedded systemComposite materialMachine Learning in Materials ScienceComputational Drug Discovery MethodsCrystallography and molecular interactions
Accurate and Interpretable Dipole Interaction Model-Based Machine Learning for Molecular Polarizability | Litcius