Neutron diffraction and phase evolution of the mechanically alloyed intermetallic compound FeZn₁₃

High-energy ball milling with subsequent annealing is used to synthesize the intermetallic compound ζ-FeZn₁₃. The mechanically alloyed phase in the as-milled state is determined to be noneqiiilibrium, or metastable. Transmission electron microscopy (TEM) studies show a highly defective microstructure with undefined grain areas, and the alloy can be described as a mechanical mixture of elemental Fe and Zn, based on neutron diffraction measurements. Characteristic stages associated with its transformation to the equilibrium state are identified based on differential scanning calorimetry (DSC) measurements. The activation energies corresponding to these stages are 128, 202, and 737 kJ/mole, respectively, with increasing transformation temperatures. The first stage is related to limited atomic diffusion or rearrangements, such as recovery, during thermal treatment, while the second stage depicts continued recrystallization and long-range atomic diffusion leading to a stable phase formation. The third and final stage marks structural decomposition of the equilibrium structure due to phase transition. Neutron diffraction of the equilibrium alloy confirmed that the structure is C2/m, with lattice parameters of a = 13.40995 A, b = 7.60586 Å, c = 5.07629 Å, and β= 127 deg 18 minutes. The atomic positions of Fe and Zn compared well to reported values.