Rare Earth materialsResearchers tackle rare Earth materials shortage

The demand for metals such as neodymium (Nd) and dysprosium (Dy) is increasing much faster than production. These metals are used in technologies such as the generators that store power in wind turbines, and the electric motors that propel electric and hybrid cars. They are also used in everyday products like computers and mobile phones.

Rare earth metals do occur in the earth’s crust, but not in sufficiently high concentrations. This is why only one country — China — has so far been supplying the entire world with these elements. SINTEF notes that in recent years, however, China has begun to restrict its export of these materials (see Stevens C. Berry, “The entertainment industry understands the rare Earth crisis, why doesn’t everybody else?” HSNW, 17 February 2014; “Chinese rare earth embargo would be ‘disastrous,’ says mining executive,” HSNW, 30 November 2011; “Industrial nations anxious about China’s rare Earth elements policy,” HSNW, 5 October 2010; and “Unease grows about China’s rare Earth elements monopoly,” HSNW, 18 October 2010). 

Forecasts show that as early as next year, these metals will be hard to come by.

SINTEF, the largest independent research organization in Scandinavia, highlights some of the rare earth materials-related initiatives in which the organization is involved:

Clean material
This explains why the recycling of rare earth metals from scrap is fast becoming an important research topic. Seven major European research institutes (Fraunhofer, CEA, TNO, VTT, SINTEF, Tecnalia, and SP) have joined forces to invest in a joint program (Value from Waste) aimed at tackling this important issue.

“The aim is to extract valuable materials from the waste streams. The challenges lie in the fact that the material must be sufficiently clean in order to be recycled, and we have to be sure that it is not contaminated by other harmful materials”, explains Odd Løvhaugen of SINTEF ICT.

Researchers are therefore focusing much of their work on finding out which products could contain pollutants, which methods are best for analyzing and measuring the content of the polluted materials, and when such products can be expected to be found in waste.

They are also evaluating extraction methods, techniques to recycle nanoparticles in the treatment process, and how the constituents of ash can be analyzed after incineration.

Technology from the aluminum and smelting industry
SINTEF is coordinating this major EU program, which is using two groups of material technologies in the race to find good analytical and extraction methods. The approach chosen by the researchers involves a technology well-known from the aluminum and smelting industry.

In the search for sources of recycling material, many people have been considering permanent magnets. This is the most significant product to contain rare earth metals — measured both in terms of value and volume.

Discarded magnets
On the basis of tests, SINTEF researchers believe that the electrolysis technology used in aluminum plants can be used to recycle magnetic alloys from discarded magnets and scrap material from magnet manufacturers. It will take some time before there are enough scrap eco-cars to be able to recycle their motors, which is why they are turning to the magnet manufacturers for the magnetic alloys.

The process is still slow, however, and there is a lot of work still to be done before the researchers will know whether they will be able to achieve their goal. If they are successful, they will have found a method that is much simpler than alternative processes based on the use of strong acids.

Solutions needed
SINTEF says that several other problems must also be solved for the stages before the electrolysis process. Among other things, there is a need to develop collection and disassembly methods for used magnets, and the magnets themselves must also be demagnetized locally, since the long-distance transport of intact permanent magnets is prohibited.

“Other challenges include finding methods that can identify and characterize nanoparticles in gases, water and solid materials”, says Odd Løvhaugen. “And we must create a toolbox of methods to evaluate the behavior of nanoparticles in waste treatment processes.”