Crystallization processes and resulting phase structure of Sm–Fe–B melt-spun ribbons
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Cited by (8)
Effect of boron additions on phase formation and magnetic properties of TbCu<inf>7</inf>-type melt spun SmFe ribbons
2016, Journal of Magnetism and Magnetic MaterialsCitation Excerpt :The magnetic and structural properties of melt spun Sm–Fe–B ribbons containing different amounts of samarium have been further investigated by Crisan et al. [5–8].
Experimental determination of the phase relations of the Sm–Fe–B ternary system at 973 K
2016, Journal of Alloys and CompoundsCitation Excerpt :The magnetostriction or magnetic properties of Sm–Fe–B alloys have been studied by using many different preparation methods, such as magnetron sputtering, melt-spinning and so on [1–9], because the Sm2Fe14B compound with high anisotropy field HA is not uniaxial and shows a strong easy plane anisotropy [10].
Study of crystallization processes in Gd-substituted Finemet alloys
2006, Journal of Alloys and CompoundsCitation Excerpt :These properties strongly depend on the average nanograin size D (the coercivity and magnetization are shown to depend on D6 [3]), and consequently of the synthesis and annealing parameters. In some previous works [5,6], we have reported on the crystallization products and the phase microstructure of fully crystallized SmxFe80 − xB20 ribbons. Below a critical Sm content xc = 8 at.
A Mössbauer investigation of amorphous Sm-Fe-B ribbons under applied field
2003, Journal of Alloys and CompoundsDirect formation of L1<inf>0</inf> FePt in as-cast FePt-based magnetic nanocomposite ribbons without post-synthesis annealing
2011, Journal of Physics D: Applied PhysicsMagnetism and phase structure of crystallized Sm-Fe-B melt spun ribbons
2002, Journal of Physics Condensed Matter