Magnetics Business & Technology - Summer 2016 - (Page 14)
FEATURE ARTICLE
Advances in Manufacture of Low or No Heavy Rare Earths NdFeB Magnets
By Shuk Rashidi and Tracy Moon, Tridus Magnetics and Assemblies, USA, in cooperation with Zhong Ke San Huan, High Tech Co.
Since its commercialization in 1983, Neodymium Iron Boron magnets have undergone
immense changes for the better in composition, integrity and unit properties.
Prior to the use of NdFeB alloys, rare earth cobalt alloys were used. The Samarium Cobalt
family of alloys were almost ideal in that they were optimized sotichiometrically for the
highest energy products (BHmax), as well as intrinsic coercive force (Hci). The Curie temperature of the Samarium family of permanent magnet was higher and the Hci almost free.
The design engineer of the magnetic circuit did not have to be overly concerned with the
loss of unit properties when the device operated continuously or intermittently at higher
temperatures. The reason being that the alloy inherently had high anisotropy of more than
300 Kilo-Oersteds and a extremely high Curie temperature.
The Emergence of Neodymium Iron Boron or NdFeB Alloy
The magnetic and physical properties of NdFeB magnets have improved steadily since
becoming commercially available.
When first introduced, this family of alloys offered BHmax that ranged between 30 to 40
MGOe. Now, production magnets are offered with energy products in excess of 55 MGOe,
and scientists have achieved as high as 59 MGOe in the lab.
The whopping increase in the energy product of these magnets is due to a host
of factors, including better handling, and more methodical manufacturing processes
combined with new methods leading to the enhancement of coercive force as well as
saturation magnetization.
The polycrystalline body of the family of NdFeB is made up of three phases; the Nd2Fe14B
phase, or the main phase, the Nd rich phase, and the phase where grain boundaries separate the two adjacent crystals. To achieve better magnetic properties it is better to increase
the ratio of the main phase to other nonmagnetic phases in the body of the alloy.
In the last twenty years, the percentage of the magnetic phase, or the Nd2Fe14B, has
gone up from 90 percent to 97 percent. This has enhanced the overall magnetic properties
of the alloy substantially. The new family of NdFeB alloys offered much higher saturation
magnetization Br, reasonably high BHmax, coupled with Hci that depended mostly on the
content of heavy rare earths (HRE).
There are generally two groups of rare earth metals that are used in many of the
NdFeB family of alloys. The light rare earth metals are related primarily to the Br of the
magnets while the level of heavy rare earth metals results in progressively higher Hci in a
given alloy. The use of the latter reduces the Br of the magnet. Light rare earths couple
ferromagnetically with the transition metal, in this case Iron, while the heavy rare earths
couple anti-ferromagnetically.
Why does the industry get so uptight about the use of light or heavy rare earths in a given
alloy? Cost. Rare earth deposits are made up of mostly light elements-Cerium, Lanthanum,
Neodymium and Samarium, while the content of the heavies, Dysprosium, Terbium, Holmium and others, represent a tiny fraction of the total. This imbalance makes the price of
the heavies substantially higher than the lights. Thus if the design engineer needs high Hci
NdFeB magnet, he has to pay more for more heavies. In a nutshell, the coercive force costs
more money in this case while in the case of Samarium based alloys this parameter was
available for free.
Figure 1.
Figure 2.
Figure 3.
Methods of Reducing the Cost of High Hci Alloys
There have been joint efforts by both manufacturers and users of NdFeB magnets to
reduce the cost of alloys with reasonable unit magnetic properties. Since there is a poor
balance in the availability of light and heavy rare earths causing large price differentials,
there has been a crusade by manufacturers to reduce the level of heavy rare earths in the
manufacture of alloys, even attempting alloys that are virtually free of heavy rare earths.
While the latter quest may be just that, much effort has been placed on one of the most
effective technique called grain boundary diffusion of heavies into the light rare earthtransition metal alloys, primarily NdFeB magnets.
Heavy Rare Earths and Their Effect on the Magnetic Properties of NdFe B Magnets
Figures (1) and (2) depict the trend in the pricing of Praseodymium-Neodymium (PrNd),
a light twin rare earth metal alloy and Dyprosium-Ferrite (Dy-Fe) alloy. Both are used in
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Magnetics Business & Technology * Summer 2016
Figure 4.
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