Abstract
Machine learning (ML) and artificial intelligence (AI) methods for modeling useful materials properties are now important technologies for rational design and optimization of bespoke functional materials. Although these methods make good predictions of the properties of new materials, current modeling methods use efficient but rather arcane (difficult‐to‐interpret) mathematical features (descriptors) to characterize materials. Data‐driven ML models are considerably more useful if more chemically interpretable descriptors are used to train them, as long as these models also accurately recapitulate the properties of materials in training and test sets used to generate and validate the models. Herein, how a particular type of molecular fragment descriptor, the signature descriptor, achieves these joint aims of accuracy and interpretability is described. Seven different types of materials properties are modeled, and the performance of models generated from signature descriptors is compared with those generated by widely used Dragon descriptors. The key descriptors in the model represent functionalities that make chemical sense. Mapping these fragments back on to exemplar materials provides a useful guide to chemists wishing to modify promising lead materials to improve their properties. This is one of the first applications of signature descriptors to the modeling of complex materials properties.
Highlights
Machine learning (ML) and artificial intelligence (AI) methods for modeling to understand the underlying molecular useful materials properties are important technologies for rational design and optimization of bespoke functional materials
We evaluated the potential of signature descriptors to solve this important issue in materials science using seven data sets with different measured properties
Comparing the neural network (BRANNGP) results derived using both types of descriptors, we see that use of Dragon descriptors required a more complicated neural network with four neurons in the hidden layer
Summary
Machine learning (ML) and artificial intelligence (AI) methods for modeling to understand the underlying molecular useful materials properties are important technologies for rational design and optimization of bespoke functional materials. These methods make good predictions of the properties of new materials, current modeling methods use efficient but rather arcane (difficult-to-interpret) mathematical features (descriptors) to characterize materials. The key goals are still not fully appreciated by descriptors in the model represent functionalities that make chemical sense Mapping these fragments back on to exemplar materials provides a useful guide to chemists wishing to modify promising lead materials to improve their properties.
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