Machine Learning of Dynamic Electron Correlation Energies from Topological Atoms Article Swipe

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van der Waals force Intermolecular force Kriging Atom (system on chip) Electronic correlation Statistical physics Topology (electrical circuits) Computer science Water dimer Electron Physics Gaussian Function (biology) Machine learning Molecule Quantum mechanics Mathematics Hydrogen bond Biology Evolutionary biology Embedded system Combinatorics

James L. McDonagh , Arnaldo F. Silva , Mark A. Vincent , Paul L. A. Popelier ·

YOU? · · 2017 · Open Access · · DOI: https://doi.org/10.1021/acs.jctc.7b01157 · OA: W2769775068

We present an innovative method for predicting the dynamic electron correlation energy of an atom or a bond in a molecule utilizing topological atoms. Our approach uses the machine learning method Kriging (Gaussian Process Regression with a non-zero mean function) to predict these dynamic electron correlation energy contributions. The true energy values are calculated by partitioning the MP2 two-particle density-matrix via the Interacting Quantum Atoms (IQA) procedure. To our knowledge, this is the first time such energies have been predicted by a machine learning technique. We present here three important proof-of-concept cases: the water monomer, the water dimer, and the van der Waals complex H<sub>2</sub>···He. These cases represent the final step toward the design of a full IQA potential for molecular simulation. This final piece will enable us to consider situations in which dispersion is the dominant intermolecular interaction. The results from these examples suggest a new method by which dispersion potentials for molecular simulation can be generated.