Canted Antiferromagnetism in Polar MnSiN2 with High N\'eel Temperature

Abstract

MnSiN2 is a transition metal nitride with Mn and Si ions displaying an ordered distribution on the cation sites of a distorted wurtzite-derived structure. The Mn2+ ions reside on a 3D diamond-like covalent network with strong superexchange pathways. We simulate its electronic structure and find that the N anions in MnSiN2 act as σ- and π-donors, which serve to enhance the N-mediated superexchange, leading to the high N\'eel ordering temperature of TN = 443 K. Polycrystalline samples of MnSiN2 were prepared to reexamine the magnetic structure and resolve previously reported discrepancies. An additional magnetic canting transition is observed at Tcant = 433 K and the precise canted ground state magnetic structure has been resolved using a combination of DFT calculations and powder neutron diffraction. The calculations favor a G-type antiferromagnetic spin order with lowering to Pc. Irreducible representation analysis of the magnetic Bragg peaks supports the lowering of the magnetic symmetry. The computed model includes a 10 rotation of the magnetic spins away from the crystallographic c-axis consistent with measured powder neutron diffraction data modeling and a small canting of 0.6.