Abstract
To explore the feasibility of deep grain-size refinement in overcoming the problem of traditional Br-Hci trade-off in bulk permanent magnets, the effect of deformation temperature on the texture strength, grain refining, and magnetic properties of slow-deformed Nd-Fe-B magnets was systematically studied. As a result, strong textures with gradual grain refining from conventionally large size of DL = 650 nm to small nanoscale size of DL = 53 nm (DL denotes the lateral size of the aligned plate-like grains) are observed as the temperature reduces from Td = 650 °C to Td = 450 °C. Moreover, magnetic observations show a simultaneous increase in remanence and coercivity as the grain refines from DL = 650 nm to DL = 127 nm. The increase in coercivity results from the grain size refinement as well as the smaller aspect ratio of the plate-like grains, and the increase in remanence results from the improved texture homogeneity. As compared with the DL = 650 nm magnets, the simultaneous increase in remanence and coercivity leads to optimum enhancements of 57% in coercivity, 10% in remanence, and 25% in energy product, which demonstrate the feasibility of near-nanoscale grain refinement in overcoming the traditional Br-Hci trade-off for improved (BH)max values. The failure of higher coercivities in the DL ≤ 80 nm magnets is closely related with the defect effects of the grain boundaries. Mechanisms explaining the grain refining and texture changing behavior were also discussed.
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