A very active area of materials research is to devise methods that use machine learning to automatically extract predictive models from existing materials data. While prior examples have demonstrated successful models for some applications, many more applications exist where machine learning can make a strong impact. To enable faster development of machine-learning-based models for such applications, we have created a framework capable of being applied to a broad range of materials data. Our method works by using a chemically diverse list of attributes, which we demonstrate are suitable for describing a wide variety of properties, and a novel method for partitioning the data set into groups of similar materials to boost the predictive accuracy. In this manuscript, we demonstrate how this new method can be used to predict diverse properties of crystalline and amorphous materials, such as band gap energy and glass-forming ability.

Last modified

• 05/08/2017

Creator

• Alok Choudhary
• Logan Ward
• Christopher Wolverton
• Ankit Agrawal

DOI

• https://doi.org/10.21985/N2VX8M

Publisher

• Springer Nature

Keyword

• computational methods
• materials for energy and catalysis
• glasses

Date created

• 2016-08-26

Related url

•  https://www.nature.com/articles/npjcompumats201628

Resource type

• Article

Source

• npj Computational Materials

License

• Attribution 3.0 United States