Rare-earth-based permanent magnets are one of the most important magnets in both scientific and industrial fields. With the development of technology, nanostructured rare-earth-based permanent magnets with high energy products are highly required. In this article, we will review the progress in chemical synthetic strategies of nanostructured rare-earth-based permanent magnets.
The double hard magnetic phase magnets with nominal compositions of Nd30–xDyxFe69B1(x=2, and 4)(wt.%) were prepared. The magnetic properties of the magnets were measured with a NIM-2000H hysteresigraph. The crystalline structures of the magnets were identified by X-ray diffraction(XRD). The Rietveld refinement was carried out using the FULLPROF software. The scanning electron microscopy(SEM) and transmission electron microscopy(TEM) analyses were carried out in order to investigate the microstructure of the magnets. It showed that the magnets consisted mainly of Nd2Fe14 B phase, and some Nd-rich phase. Two types of matrix-phase grains in dark grey and light grey were found in the magnets with x=2 and 4. The Dy content was obviously different in the two types of grains, which proved that the double hard magnetic phases(Dy-rich and Dy-lean phases) coexisted in the magnet. It revealed that the Nd-rich phases in junction regions had fcc structure, with the unit cell parameter of about 0.52–0.56 nm. The weak superlattice spots were found in the SAD patterns of the junction Nd-rich phases with large scale. The double hard magnetic phase structure seemed to improve the magnetic properties of NdFeB magnets with high coercivity, while decrease the consumption of Dy element, compared with the single alloy magnet.
Anisotropic CeC o4.325-xCu0.675Fex(x = 0.475-0.875) sintered magnets were prepared by traditional powder metallurgical method. Influence of ball-milling time and iron content on microstructure and magnetic properties of the CeC o4.325-xCu0.675 Fexsintered magnets were investigated. It is shown that the properties of the magnet produced by magnetic powders ball-milled for 40 min are better than that for 30 min. With iron content increasing, remanence Brand maximum energy product(BH)mincrease first and then decrease.The optimal magnetic properties are obtained for the CeC o3.65Cu0.675Fe0.675 sintered magnet: Br= 0.685 T, the intrinsic coercivity Hci= 350 kA ám-1, and(BH)m=85.6 kJ ám-3. The increase of Bris mainly influenced by iron content of 1:5 matrix which can properly increase the saturation induction Bs; the rapid increase of the amount of Ce-rich phase and 5:19 phase gives rise to the deterioration of the magnets when x C 0.775.
Wei SunMing-Gang ZhuYi-Kun FangWei PanMan-Long XiaWei Li
The microstructures and magnetic properties of Ce-32.15Co_49.36Cu_9.84Fe_9.65 magnet sintered at the temperatures ranging from 1005 to 1105 °C were investigated. The results on scanning electron microscopy and X-ray diffraction analysis indicate that the remanence B r of the magnets is mainly influenced by the degree of the easy-axis orientation when sintering temperature is less than 1085 °C, the rapidly increasing amount of the secondly phase (5:19 phase) gives rise to the deterioration of the magnetic properties of the magnet above 1085 °C. Moreover, it is found that intrinsic coercivity H ci is strongly related to the content of copper in the matrix of the sintered magnets. The optimal sintering temperature is located in 1025~1055 °C, the corresponding magnetic properties of the magnets are B_r =0.685T, H_(ci) =350kA·m^-1 , and maximum energy product (BH)_m =85.6 kJ·m 3 .
SUN Wei ZHU Minggang FANG Yikun PAN Wei LI Jiajie LI Yanfeng LI Wei
Nanomagnetism is the origin of many unique properties in magnetic nanomaterials that can be used as building blocks in information technology, spintronics, and biomedicine. Progresses in nanomagnetic principles, distinct magnetic nanostructures, and the biomedical applications of nanomagnetism are summarized.
