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Atomic-scale defects in the two-dimensional ferromagnet CrI <sub>3</sub> from first principles

Michele Pizzochero

2020Journal of Physics D Applied Physics36 citationsDOIOpen Access PDF

Abstract

Abstract The family of atomically thin magnets holds great promise for a number of prospective applications in magneto-optoelectronics, with CrI 3 arguably being its most prototypical member. However, the formation of defects in this system remains unexplored to date. Here, we investigate native point defects in monolayer CrI 3 by means of first-principles calculations. We consider a large set of intrinsic impurities and address the atomic structure, thermodynamic stability, diffusion and aggregation tendencies as well as local magnetic moments. Under thermodynamic equilibrium, the most stable defects are found to be either Cr or I atomic vacancies along with their complexes, depending on the chemical potential conditions. These defects are predicted to be quite mobile at room and growth temperatures, and to exhibit a strong tendency to agglomerate. In addition, our calculations indicate that the deviation from the nominal stoichiometry largely impacts the magnetic moments, and the defect-induced lattice distortions can drive local ferromagnetic-to-antiferromagnetic phase transitions. Overall, this work portrays a comprehensive picture of intrinsic point defects in monolayer CrI 3 from a theoretical perspective.

Topics & Concepts

FerromagnetismCondensed matter physicsCrystallographic defectMonolayerMaterials scienceStoichiometryLattice (music)ImpurityWork (physics)DiffusionTopological defectPhase (matter)MagnetCurie temperatureChemical physicsMagnetic fieldAtomic unitsChemistryMagnetic moment2D Materials and ApplicationsHeusler alloys: electronic and magnetic propertiesElectronic and Structural Properties of Oxides