TEM study of microstructural changes in an anisotropic Nd-Fe-Co-B-Zr magnet alloy during HDDR process

Changes in microstructure of Nd-Fe-Co-B-Zr alloy powder during the hydrogenation-decomposition-desorption-recombination (HDDR) process have been investigated in detail by transmission electron microscopy (TEM). It was found that the microstructural changes in the HDDR process start with the formation of cellular NdH₂ and α-(Fe, Co) at a temperature between 933 and 973 K. The starting temperature is about 50 K higher than that of the Nd-Fe-B ternary system. By further annealing at 973 K, colonies of rod-shaped NdH₂ and spherical grains of NdH₂ grow, embedded in the α-(Fe, Co) matrix. It was confirmed by the selected area electron diffraction (SAED) analysis that there is no specific crystallographic orientation relationship between the original Nd₂(Fe, Co)₁₄B and the decomposed phases; NdH₂ and α-(Fe, Co). (Fe, Co)₂B grains appear above 973 K, but the number density of the grains is very small. These features suggest that none of the NdH₂, the α-(Fe, Co) and the (Fe, Co)₂B transfers the c-axis of the original Nd₂(Fe, Co)₁₄B to the recombined one. The microstructure formed at 1073-1103 K consists mainly of fine spherical NdH₂ particles and α-(Fe, Co) matrix. Most of the NdH₂ particles are covered with rims. The SAED and EDX analyses confirmed that the rim regions are made of Nd₂(Fe, Co)₁₄B crystalline grains which are strongly correlated with one another in the crystal orientation. After a short treatment of hydrogen desorption, the rim-like phases grow up to form a microcrystalline structure of Nd₂(Fe, Co)₁₄B.