Title :
Increase of Coercivity and Composition Distribution in Fluoride-Diffused NdFeB Sintered Magnets Treated by Fluoride Solutions
Author :
Komuro, Matahiro ; Satsu, Yuichi ; Suzuki, Hiroyuki
Author_Institution :
Adv. Res. Lab., Hitachi, Ltd., Hitachi, Japan
Abstract :
Rare-earth and fluorine were diffused along grain boundaries in NdFeB sintered magnets during heat treatment after rare-earth fluoride liquid coating. In the case of Dy fluoride coating, the coercivity for NdFeB sintered magnets with a thickness of 1 mm after the diffusion was increased from 0.80 MA/m to 1.13 MA/m (41%) with remanence reduction of 0.6%. Segregations for Dy atoms near the grain boundaries and fluorine atoms at the grain boundary were found by TEM observations. The increase of coercivity per the weight of the rare-earth fluorides has a correlation with the anisotropy field of the RE2Fe14B (RE is rare-earth elements). Furthermore, the Dy quantity required for the observed increase of coercivity can be reduced to 1/3 compared to the previous NdFeB sintered magnets using the fluoride coating and diffusion process.
Keywords :
boron alloys; coatings; coercive force; diffusion; dysprosium compounds; grain boundaries; heat treatment; iron alloys; lanthanum compounds; magnetic anisotropy; magnets; neodymium alloys; neodymium compounds; praseodymium compounds; remanence; segregation; sintering; terbium compounds; DyF; LaF; NdF; NdFeB; PrF; TEM observations; TbF; anisotropy field; coercivity; composition distribution; fluoride solutions; fluoride-diffused sintered magnets; grain boundaries; heat treatment; rare-earth fluoride liquid coating; rare-earth metals; remanence reduction; segregations; size 1 mm; Anisotropic magnetoresistance; Coatings; Coercive force; Diffusion processes; Grain boundaries; Iron; Magnetic anisotropy; Magnetic field measurement; Magnetic flux; Magnetic resonance imaging; Magnetometers; Magnets; Perpendicular magnetic anisotropy; Remanence; Anisotropy; Nd$_2$Fe$_{14}$ B; coating; coercivity; rare-earth magnet; sintered magnet;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2010.2064780
