Structural phase transitions, mechanical properties, and electronic band structures of room-temperature ferromagnetic monolayers ScMP2 (M = Mn and Cr)

•Three stable tetragonal monolayers ScMP2 (M = Mn and Cr) with room-temperature ferromagnetism have been predicted.•The values of in-plane negative Poisson’s ratio and perpendicular magnetic anisotropic energy can be greatly improved simultaneously in the structural phase transitions from square ScC...

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Published in:Results in physics Vol. 53; p. 106988
Main Authors: Xie, Xiao, Chen, Mengteng, Yu, Yawei, Li, Jia, Zhao, Mingwen, Li, Linyang
Format: Journal Article
Language:English
Published: Elsevier B.V 01-10-2023
Elsevier
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Summary:•Three stable tetragonal monolayers ScMP2 (M = Mn and Cr) with room-temperature ferromagnetism have been predicted.•The values of in-plane negative Poisson’s ratio and perpendicular magnetic anisotropic energy can be greatly improved simultaneously in the structural phase transitions from square ScCrP2 to rectangular ScCrP2, originating from the coupling mechanism of ferroelasticity and ferroelectricity.•The Dirac half-metal band structures can be found in the monolayers ScMP2, and the ScMnP2 is a half-Chern insulator. Two-dimensional (2D) auxetic properties and ferromagnetism are two major focuses of research for next-generation nanomechanical and spintronic devices. However, 2D materials with the two properties at the same time are rarely reported. Based on first-principles calculations, we propose the 2D bimetallic phosphide ScMP2 (M = Mn and Cr), including three stable tetragonal monolayers. The monolayer ScMnP2 exhibit the square structural phase while there is a structural phase transition between the square ScCrP2 and the rectangular ScCrP2, which originates from the mechanism of ferroelasticity and ferroelectricity. Both monolayers ScCrP2 exhibit in-plane auxetic properties, and the value of the negative Poisson’s ratio can reach –0.322. All the three monolayers show a ferromagnetic ground state with high Curie temperature, and are a Dirac half-metal without spin–orbit coupling (SOC). When considering SOC, a nontrivial bandgap can be found in the monolayer ScMnP2, which further becomes a half-Chern insulator. Importantly, the structural phase transitions from the square lattice to the rectangular lattice in the monolayers ScCrP2 will enable a significant improvement in the values of negative Poisson’s ratio and magnetic anisotropic energy simultaneously. Taking the multiferroic (ferroelastic, ferroelectric, and ferromagnetic), auxetic, and topological properties into consideration, the 2D system of ScMP2 provide promising applications for future multifunctional nanodevices.
ISSN:2211-3797
2211-3797
DOI:10.1016/j.rinp.2023.106988