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Machine learned synthesizability predictions aided by density functional theory

Andrew S. Lee, Suchismita Sarker, James E. Saal, Logan Ward, Christopher K. H. Borg, Apurva Mehta, Christopher Wolverton

2022Communications Materials28 citationsDOIOpen Access PDF

Abstract

Abstract A grand challenge of materials science is predicting synthesis pathways for novel compounds. Data-driven approaches have made significant progress in predicting a compound’s synthesizability; however, some recent attempts ignore phase stability information. Here, we combine thermodynamic stability calculated using density functional theory with composition-based features to train a machine learning model that predicts a material’s synthesizability. Our model predicts the synthesizability of ternary 1:1:1 compositions in the half-Heusler structure, achieving a cross-validated precision of 0.82 and recall of 0.82. Our model shows improvement in predicting non-half-Heuslers compared to a previous study’s model, and identifies 121 synthesizable candidates out of 4141 unreported ternary compositions. More notably, 39 stable compositions are predicted unsynthesizable while 62 unstable compositions are predicted synthesizable; these findings otherwise cannot be made using density functional theory stability alone. This study presents a new approach for accurately predicting synthesizability, and identifies new half-Heuslers for experimental synthesis.

Topics & Concepts

Ternary operationStability (learning theory)Density functional theoryRecallComputer scienceMachine learningArtificial intelligenceMaterials scienceChemistryComputational chemistryPsychologyCognitive psychologyProgramming languageMachine Learning in Materials ScienceInorganic Chemistry and MaterialsX-ray Diffraction in Crystallography
Machine learned synthesizability predictions aided by density functional theory | Litcius