Calculation of energy and magnetic susceptibility of Fe atomic system during dislocation motion in magnetic field

Author:

Kraiev MaksymORCID,Voronkov EugeneORCID,Kraieva VioletaORCID

Abstract

PurposeThe purpose is to calculate the change in the total energy of a small fragment of an idealized lattice of iron (in its pure form and with impurity atoms) containing an edge dislocation during its elementary motion at one interatomic spacing, both under the influence of a constant magnetic field and without it. The introduction of a magnetic field into the system is aimed at checking the adequacy of the description of the phenomenon of magnetoplasticity by changing the total energy of the atomic system.Design/methodology/approachThe design procedure is based on a quantum-mechanical description of the switching process of the covalent bond of atoms in the dislocation core. The authors used the method of density functional theory in the Kohn-Shem version, implemented in the GAUSSIAN 09 software package. Using the perturbation theory, the authors modeled the impact of an external constant magnetic field on the energy of a system of lattice atoms.FindingsThe simulation results confirmed the effect of an external constant magnetic field on the switching energy of the covalent bond of atoms in the dislocation core, and also a change in the magnetic susceptibility of a system of atoms with a dislocation. This complements the description of the magnetoplastic effect during the deformation of metals.Originality/valueThe authors created quantum-mechanical models of the dislocation motion in the Fe crystal lattice: without impurities, with a substitutional atom Cr and with an interstitial atom C. The models take into account the influence of an external constant magnetic field.

Publisher

Emerald

Subject

Mechanical Engineering,Mechanics of Materials,General Materials Science,Modeling and Simulation

Reference16 articles.

1. Resonance magnetoplasticity in ultralow magnetic fields;JETP Letters,2016

2. Structural, electronic, magnetic and thermoelectric properties of Full-Heusler Fe2MnSi: Ab Initio calculations;Results in Physics,2020

3. Magnitoplastichnost' tverdykh tel (obzor) [Magnetoplasticity of solids (review)];Fizika Tverdogo Tela [Solid State Physics],2004

4. Tensile properties and microstructure of 2024 aluminum alloy subjected to the high magnetic field and external stress;Chinese Physics B,2016

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