Crystallographic and Magnetic Properties of Solid Solutions of the Phosphides M2P, M = Cr, Mn, Fe, Co, and Ni

Abstract

Several phosphides with the chemical formula M₂P crystallize in a hexagonal structure: Mn₂P, Fe₂P, and Ni₂P. The structure of Co₂P is orthorhombic. These two structures are related via an identical elementary subcell consisting of a tetrahedral‐site and a pyramidal‐site M‐atom pair. This investigation shows that solid solutions between two hexagonal end members, such as Fe₂P or Ni₂P with Mn₂P, may exhibit orthorhombic structures at intermediate compositions. Fe₂P shows complete solid solubility with Ni₂P. Curiously, hexagonal and orthorhombic symmetries alternate with decreasing number of 3d electrons, Ni₂P(hex) ‐Co₂P(ortho) ‐Fe₂P(hex) ‐FeMnP(ortho) ‐Mn₂P(hex). Lattice parameter variations with composition and Mössbauer studies reveal atomic ordering in the mixed systems, Mn and Cr substituting for pyramidal‐site iron in FeMnP and FeCrP while Ni and Co substitute preferentially for tetrahedralsite iron in FeCoP and FeNiP. While neither Co₂P nor Mn₂P are ferromagnetic, intermediate phases are, the Curie temperature and magnetization reaching the maximum values 310°C and 3.03 μ_B/molecule for MnCoP. Metamagnetism appears for a range of compositions about (Mn_0.7Co_0.3)₂P. The Co₂P‐Fe₂P system is also ferromagnetic with a maximum Curie temperature near FeCoP. This system shows a sharp discontinuity in magnetization, but only a small discontinuity in Curie temperature, across the phase transition. Sensitivity to stoichiometry in the magnetization of Fe_2‐εP is attributed to an electron/atom ratio near that for the appearance of metamagnetism.