Synthesis of ε-Fe_xN (2≤x≤3) Submicron Particles and the Diffusion Mechanism of Nitrogen Atoms

Abstract

We synthesized submicron-sized ε-Fe_xN (2≤x≤3) particles by heating 180-nm Fe₃O₄ particles in an atmosphere of NH₃, both with and without H₂, and we studied their structural and magnetic properties. The nitride samples (first step nitridation) prepared by NH₃ and annealed at 623 K (ε-Fe₂N) had an expanded unit cell and were paramagnetic at room temperature. The purpose of H₂ annealing, which was successively applied on the first step nitride sample, was to dissolve excess nitrogen atoms and reduce the lattice constant. The nitrogen concentrations were estimated from X-ray diffraction patterns. Saturation magnetization was found to increase with the H₂ annealing time. The nitrogen diffusion constant in the submicron hcp particles was found to be 6.33×10⁻²⁰ m²/s, which is about three orders of magnitude smaller than that of the bulk hcp iron nitrides. This may result from the coating materials, such as SiO₂ and others, covering the inner core nitrides, where nitrogen atoms passed through during diffusion.