The growth of the clean energy industry in the United States (US) has stimulated concern about the availability of critical materials for energy. These materials include several rare-earth elements and are key components in many clean energy technologies such as wind turbines, electric vehicles, energy-efficient lighting, and solar panels. While the US is estimated to have nearly 12% of the world’s rare-earth reserves, China has dominated global rare-earth production and supply for more than two decades, peaking at nearly 98% of global supply in 2010 and providing over 85% in 2012. In addition to the rare-earth elements, indium and tellurium (used in thin-film solar cells) and lithium (used in batteries) are also critical materials for clean energy technologies.

The health of the clean energy economy in the US hinges both on diversifying supply for these important materials (which will include developing a domestic supply chain) and on finding innovative ways to reduce the need for them. The importance of finding new solutions to address shortages in critical materials has been widely accepted in the materials community and the US government since 2010 when China had temporarily cut off rare-earth supplies to Japan. Since then, China has also imposed restrictions on the amount of rare earths it exports, and Congressional lawmakers have been grappling with the best way to address domestic critical materials shortages. Although several rare-earth and critical materials bills have been introduced in the last two Congresses, none have gained the necessary support to become law.

The US Administration has also recognized the dangers of critical materials shortages and has instituted a number of initiatives to improve domestic materials capabilities. In 2011, President Obama launched the Materials Genome Initiative, a multi-agency effort to speed the discovery of new materials and decrease the cost of their deployment to the market. Further efforts have been made through the Department of Energy (DOE), which has supported research on a range of advanced materials and clean energy technologies. In January 2013, the DOE announced its latest Energy Innovation Hub, the Critical Materials Institute (CMI), which has been awarded $120 million to fund research for the next five years.

Alexander King, director of Ames Laboratory, has been named director of the new Hub. The CMI brings together researchers from academia and four DOE national laboratories to collaborate with industry leaders and find solutions to the critical materials issues the US now faces. The focus of the CMI is multidirectional—researchers plan to address domestic supply-chain issues as well as improve critical materials recycling and develop new substitute materials with more abundant, economically feasible supplies.

Photo courtesy of The Ames Laboratory, USDOE.

Ames Laboratory played a key role in convening the CMI team. CMI partners include Idaho, Lawrence Livermore and Oak Ridge National Laboratories; Brown University; Colorado School of Mines; Iowa State University; Purdue University; Rutgers University; University of California–Davis; Florida Industrial and Phosphate Research Institute, and industry partners Advanced Recovery; Cytec, Inc.; General Electric; Molycorp, Inc.; OLI Systems, Inc.; Simbol Materials; and SpinTek Filtration, Inc. According to King, “the Hub has to actually solve problems, and do so quickly and effectively. That was the philosophy that went into building this team.”

The research carried out by the CMI partners will be driven by life cycle, economic, and policy analysis. This approach is best illustrated by looking at relevant materials examples like neodymium versus terbium and europium. Neodymium is used in magnets—from the very small like those in ear bud speakers to the very large like those in wind turbines and electric vehicle motors. These latter two clean energy technologies use huge amounts of neodymium, vastly increasing demand for the resource. Policy decisions will have a significant impact on the deployment of these technologies, and therefore on the demand for the resource. In this case, the viable solution to address increased neodymium demand is to diversify and increase supply—perhaps by enabling the US to exploit its own natural resources to produce these elements.

On the other hand, terbium and europium are used in very small amounts in computer screens and fluorescent lights to adjust color. While the current trend for increased efficiency in lighting is driving a transition from incandescent bulbs to fluorescent lights, it is likely that fluorescent lights will eventually also be replaced by more efficient technologies like light-emitting diodes. This means that there will be a small increase in demand for terbium and europium that will eventually wane. The increased demand for these two rare-earth elements can be met largely by recycling and reuse while also developing substitute technologies in parallel.

As technologies and materials supplies develop, the very definition of what is critical is constantly changing. According to Rod Eggert, director of the Colorado School of Mines Division of Economics and Business and deputy director of the CMI, “what is unusual about the CMI is the close coupling of economic analysis with science and engineering research. The economic analysis will directly inform annual decisions about which research projects to continue, which to stop, and which new research areas should be pursued.”

While the important task of finding new solutions to address shortages in energy critical materials will continue to be a challenge for researchers and policymakers alike, the establishment of the CMI is an important step in securing the future of the US clean energy economy.