Litcius/Paper detail

Coevolutionary search for optimal materials in the space of all possible compounds

Zahed Allahyari, Artem R. Oganov

2020npj Computational Materials38 citationsDOIOpen Access PDF

Abstract

Abstract Over the past decade, evolutionary algorithms, data mining, and other methods showed great success in solving the main problem of theoretical crystallography: finding the stable structure for a given chemical composition. Here, we develop a method that addresses the central problem of computational materials science: the prediction of material(s), among all possible combinations of all elements, that possess the best combination of target properties. This nonempirical method combines our new coevolutionary approach with the carefully restructured “Mendelevian” chemical space, energy filtering, and Pareto optimization to ensure that the predicted materials have optimal properties and a high chance to be synthesizable. The first calculations, presented here, illustrate the power of this approach. In particular, we find that diamond (and its polytypes, including lonsdaleite) are the hardest possible materials and that bcc-Fe has the highest zero-temperature magnetization among all possible compounds.

Topics & Concepts

Space (punctuation)Computer scienceComputational biologyArtificial intelligenceBiologyOperating systemMachine Learning in Materials ScienceHistory and advancements in chemistryThermal and Kinetic Analysis