Substitution- and Strain-induced Magnetic Phase Transition in Iron Carbide

TL;DR

This study uses first-principles calculations to explore how Cr substitution and strain induce magnetic phase transitions in iron carbide, revealing a transition from ferromagnetic to nonmagnetic phases with potential applications in magnetocaloric technology.

Contribution

It demonstrates how Cr substitution and strain can control magnetic phases in Fe3C, introducing a new way to tune magnetic properties in cementite-type carbides.

Findings

Cr substitution causes a second-order magnetic phase transition.

Magnetization can be tuned via strain effects.

Magnetic-nonmagnetic transition occurs at x=2 in Fe3-xCrxC.

Abstract

Cementite-type carbides are of interest for magnetocaloric applications owing to their temperature- or pressure-induced magnetic phase transition. Here, using first-principles calculations, we investigate the magnetism and the magnetic phase transition in iron carbide (Fe3C) with the substitution of Cr atoms at Fe sites with the strain effect. The presence of Cr atoms is found to give rise to a second-order magnetic phase transition from a ferromagnetic phase for Fe3C to a nonmagnetic phase in chromium carbide (Cr3C).While the ternary Fe2CrC and Cr2FeC compounds prefer the ferrimagnetic ground state, the magnitudes of both the Fe and Cr spin moments, which are antiparallel in orientation, decrease as x increases in Fe3-xCrxC (x = 0, 1, 2, and 3). Furthermore, the fixed spin-moment calculations indicate that the magnetization of Fe3-xCrxC compounds can be delicately altered via the strain effect and that the magnetic-nonmagnetic phase transition occurs at an early stage of Cr substitution, x = 2.