Predicting Electronic Structure Properties of Transition Metal Complexes with Neural Networks
Jon Paul Janet, Heather J. Kulik

TL;DR
This paper introduces neural networks trained on simple empirical inputs to accurately predict quantum-mechanical properties of transition metal complexes, improving transferability and enabling efficient high-throughput screening.
Contribution
The study presents a novel ANN model that predicts spin-state properties of transition metal complexes using transferable descriptors without needing detailed 3D structures.
Findings
ANN predicts spin-state splittings within 3 kcal/mol of DFT
Model outperforms support vector and kernel ridge regression
Uncertainty quantification improves prediction reliability
Abstract
High-throughput computational screening has emerged as a critical component of materials discovery. Direct density functional theory (DFT) simulation of inorganic materials and molecular transition metal complexes is often used to describe subtle trends in inorganic bonding and spin-state ordering, but these calculations are computationally costly and properties are sensitive to the exchange-correlation functional employed. To begin to overcome these challenges, we trained artificial neural networks (ANNs) to predict quantum-mechanically-derived properties, including spin-state ordering, sensitivity to Hartree-Fock exchange, and spin- state specific bond lengths in transition metal complexes. Our ANN is trained on a small set of inorganic-chemistry-appropriate empirical inputs that are both maximally transferable and do not require precise three-dimensional structural information for…
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