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Frenkel pair formation energy for cubic Fe<sub>3</sub>O<sub>4</sub> in DFT + U calculations

Margarita I. Shutikova, Vladimir Stegailov

2022Journal of Physics Condensed Matter12 citationsDOIOpen Access PDF

Abstract

Abstract The cubic phase of magnetite is stabilized above the Verwey transition temperature of about 120 K via a complex electron–phonon interaction that is still not very well understood. In this work using the DFT + U method we describe our attempt to calculate point defect formation energies for this cubic phase in the static approximation. The electronic structure calculations and atomic relaxation peculiarities are discussed in this context. Only the cubic phase model with a small band gap and charge disproportionation (Fe 2+ /Fe 3+ ) gives an adequate point defect formation energies, not the semi-metallic model. The relaxation of the local defect atomic structure and the relaxation of the surrounding crystal matrix are analyzed. Point defects cause only local perturbations of atomic positions and charge-orbital order. After analysis of the supercell size effects for up to 448 atoms, we justify the use of small supercells with 56 atoms to make calculations for the cubic phase. The extensive experimental results of Dieckmann et al on defects in magnetite at high temperature are deployed for comparison of our DFT + U results on Frenkel pair formation energies.

Topics & Concepts

SupercellCondensed matter physicsCubic crystal systemCrystallographic defectRelaxation (psychology)Charge orderingPhase (matter)Materials scienceContext (archaeology)Charge (physics)PhysicsQuantum mechanicsMeteorologyPsychologyPaleontologyBiologyThunderstormSocial psychologyMagnetic Properties and Synthesis of FerritesAdvancements in Battery MaterialsBauxite Residue and Utilization
Frenkel pair formation energy for cubic Fe<sub>3</sub>O<sub>4</sub> in DFT + U calculations | Litcius