Litcius/Paper detail

Magnetic properties of hematite revealed by an <i>ab initio</i> parameterized spin model

Tobias Dannegger, András Deák, Levente Rózsa, Edgar Galindez‐Ruales, Shubhankar Das, Eunchong Baek, Mathias Kläui, L. Szunyogh, U. Nowak

2023Physical review. B./Physical review. B22 citationsDOI

Abstract

Hematite is a canted antiferromagnetic insulator, promising for applications in spintronics. Here we present ab initio calculations of the tensorial exchange interactions of hematite and use them to understand its magnetic properties by parametrizing a semiclassical Heisenberg spin model. Using atomistic spin dynamics simulations, we calculate the equilibrium properties and phase transitions of hematite, most notably the Morin transition. The computed isotropic and Dzyaloshinskii--Moriya interactions result in a N\'eel temperature and weak ferromagnetic canting angle that are in good agreement with experimental measurements. Our simulations show how dipole-dipole interactions act in a delicate balance with first and higher-order on-site anisotropies to determine the material's magnetic phase. Comparison with spin-Hall magnetoresistance measurements on a hematite single crystal reveals deviations of the critical behavior at low temperatures. Based on a mean-field model, we argue that these differences result from the quantum nature of the fluctuations that drive the phase transitions.

Topics & Concepts

HematiteParameterized complexityAb initioSpin (aerodynamics)Condensed matter physicsMaterials scienceTheoretical physicsPhysicsComputational chemistryChemistryMathematicsCombinatoricsThermodynamicsMineralogyQuantum mechanicsIron oxide chemistry and applicationsGeomagnetism and Paleomagnetism StudiesCharacterization and Applications of Magnetic Nanoparticles