2D-XY ferromagnetism with high transition temperature in Janus monolayer V2XN (X = P, As)

Abstract

Two-dimensional (2D) XY magnets with easy magnetization planes support the nontrivial topological spin textures whose dissipationless transport is highly desirable for 2D spintronic devices. Here, we predicted that Janus monolayer V2XN (X = P, As) with a square lattice are 2D-XY ferromagnets by first-principles calculations. Both the magnetocrystalline anisotropy and magnetic shape anisotropy favor an in-plane magnetization, leading to an easy magnetization xy-plane in Janus monolayer V2XN. Resting on the Monte Carlo simulations, we observed the Berezinskii-Kosterlitz-Thouless (BKT) phase transition in monolayer V2XN with transition temperature T BKT being above the room temperature. Especially, monolayer V2AsN has a magnetic anisotropy energy (MAE) of 292.0 μeV per V atom and a T BKT of 434 K, which is larger than that of monolayer V2PN. Moreover, a tensile strain of 5\% can further improve the T BKT of monolayer V2XN to be above 500 K. Our results indicated that Janus monolayer V2XN (X = P, As) were candidate materials to realize high-temperature 2D-XY ferromagnetism for spintronics applications.