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An accelerating approach of designing ferromagnetic materials via machine learning modeling of magnetic ground state and Curie temperature

Teng Long, Nuno M. Fortunato, Yixuan Zhang, Oliver Gutfleisch, Hongbin Zhang

2021Materials Research Letters50 citationsDOIOpen Access PDF

Abstract

Magnetic materials have a plethora of applications from information technologies to energy harvesting. However, their functionalities are often limited by the magnetic ordering temperature. In this work, we performed random forest on the magnetic ground state and the Curie temperature (TC) to classify ferromagnetic and antiferromagnetic compounds and to predict the TC of the ferromagnets. The resulting accuracy is about 87% for classification and 91% for regression. When the trained model is applied to magnetic intermetallic materials in Materials Project, the accuracy is comparable. Our work paves the way to accelerate the discovery of new magnetic compounds for technological applications.

Topics & Concepts

FerromagnetismCurie temperatureMaterials scienceAntiferromagnetismGround stateCondensed matter physicsRandom forestIntermetallicMachine learningWork (physics)Artificial intelligenceMagnetCurieMagnetic domainEnergy (signal processing)Magnetic shape-memory alloyState (computer science)Magnetic structureComputer scienceCurie–Weiss lawMachine Learning in Materials ScienceInorganic Chemistry and MaterialsHeusler alloys: electronic and magnetic properties