Ferromagnetic half-metal with high Curie temperature: Janus Mn2PAs monolayer

Two-dimensional (2D) Janus materials with mirror asymmetry exhibit fascinating physical properties, implying wide applications in nanoscale optoelectronic and piezoelectric devices. However, intrinsic ferromagnetic (FM) Janus monolayers with high Curie temperature (T-c) and large magnetic anisotropic energy (MAE) are rarely reported. By performing the first-principles calculations, the electronic structure and magnetic properties of stable Janus Mn2PAs monolayer were investigated. We found that Mn2PAs monolayer is FM halfmetal with high T-c of 557 K and easy out-of-plane magnetization axis, as well as a small intrinsic electric polarization. Additionally, Mn2PAs monolayer under biaxial strain from -10% to 10% remains to be FM half-metallic. More importantly, the MAE reaches a maximum value of similar to 578 leV per Mn atom under 8% tensile strain and changes direction under compressive strain larger than 2%, which mainly attributes to the variation of (p(y), p(z))/(p(y), p(x)) orbital matrix elements of As/P atom. The desired and robust ferromagnetism and half-metallicity with 100% spin-polarization of Janus Mn2PAs monolayer enrich the application of 2D Janus materials in nanoscale spintronic devices.

Automated summary

The research investigated the electronic structure and magnetic properties of two-dimensional Janus Mn2PAs materials with mirror asymmetry, revealing high Curie temperature and magnetic anisotropic energy along with maintaining ferromagnetism under biaxial strain. This study enriches the application of 2D Janus materials in nanoscale spintronic devices.