Electron microscopy and the study of microstructure and domain structure of magnetic materials
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Improvement of magnetic performance of hot-deformed Nd-Fe-B magnets by secondary deformation process after Nd-Cu eutectic diffusion
2016, Acta MaterialiaCitation Excerpt :Studies on coercivity mechanism either by domain wall pinning model [28,29] or nucleation model of reversed domains [12,30] have been carried out by many researchers. Many Lorentz transmission electron microscopy observations suggest strong domain wall pinning by grain boundary [14,19,31,32]. The domain wall pinning at the grain boundaries phase was also observed in sintered Nd-Fe-B magnet with the average grain size of 380 nm even at 225 °C [33].
Dynamic magnetization observations and reversal mechanisms of sintered and die-upset Nd-Fe-B magnets
2000, Journal of Magnetism and Magnetic MaterialsMagnetic nanostructures: Synthesis, properties, and applications
2013, Springer Handbook of NanomaterialsInverse analysis of flow behaviour of AISI 304 stainless steel casing and Nd-Fe-B magnet at different strain rates
2011, Materials Science and Technology
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