Litcius/Paper detail

Materials discovery through machine learning formation energy

Gordon G. C. Peterson, Jakoah Brgoch

2021Journal of Physics Energy76 citationsDOIOpen Access PDF

Abstract

Abstract The budding field of materials informatics has coincided with a shift towards artificial intelligence to discover new solid-state compounds. The steady expansion of repositories for crystallographic and computational data has set the stage for developing data-driven models capable of predicting a bevy of physical properties. Machine learning methods, in particular, have already shown the ability to identify materials with near ideal properties for energy-related applications by screening crystal structure databases. However, examples of the data-guided discovery of entirely new, never-before-reported compounds remain limited. The critical step for determining if an unknown compound is synthetically accessible is obtaining the formation energy and constructing the associated convex hull. Fortunately, this information has become widely available through density functional theory (DFT) data repositories to the point that they can be used to develop machine learning models. In this Review, we discuss the specific design choices for developing a machine learning model capable of predicting formation energy, including the thermodynamic quantities governing material stability. We investigate several models presented in the literature that cover various possible architectures and feature sets and find that they have succeeded in uncovering new DFT-stable compounds and directing materials synthesis. To expand access to machine learning models for synthetic solid-state chemists, we additionally present MatLearn . This web-based application is intended to guide the exploration of a composition diagram towards regions likely to contain thermodynamically accessible inorganic compounds. Finally, we discuss the future of machine-learned formation energy and highlight the opportunities for improved predictive power toward the synthetic realization of new energy-related materials.

Topics & Concepts

Computer scienceMachine learningArtificial intelligenceCheminformaticsField (mathematics)Materials informaticsChemistryHealth informaticsMathematicsComputational chemistryEngineering informaticsPure mathematicsPublic healthNursingMedicineMachine Learning in Materials ScienceComputational Drug Discovery MethodsX-ray Diffraction in Crystallography