Mn-doped ZnSnAs₂ chalcopyrite structure is one of the most important material to realize semiconductor spintronics because of its high Curie temperature [1-2].
In this work, we study theoretically electronic and magnetic properties of Mn-doped ZnSnAs₂ chalcopyrite structure by using first-principles all electron full-potential linearized augmented plane wave (FP-LAPW) method based on density functional theory (DFT). Our calculations were performed for supercells, containing 64 and 128 atoms with the Mn concentrations 3.125% and 6.25%. We studied when Mn magnetic impurity substitutes a single cation (Mn_Zn and Mn_Sn) or both of the two cation sites (Mn_Zn-Sn). From the total energy calculations for 64 atom supercells doped with Mn atoms in Zn-Zn sites were found to be energetically stable in the AFM state. The substitution of Zn-Sn and Sn-Sn positions results in the FM state (Fig.1). In the FM configurations calculated magnetic moment for each Mn is about 4.23μ_B and 3.99 μ_B per unit cell when Zn-Sn and Sn-Sn positions were substituted, respectively. The Curie temperature values are roughly estimated from the mean-field approximation.