Sourcing rare earth elements from rock waste

March 07, 2019 // By Nick Flaherty
Sourcing rare earth elements from rock waste
Researchers in the Us have developed a technique to separate vital rare earth elements (REE) such as cerium, neodymium and dysprosium from rock waste.

The approach could benefit clean energy technology, according to researchers at Rutgers University–New Brunswick and other members of the Critical Materials Institute, a US Department of Energy effort aimed at bolstering supply chains for materials important to clean energy.

REEs are essential for technologies such as solar and wind energy and advanced vehicles, along with modern electronics like smartphones. China produces roughly 90 percent of all such elements and there is a global shortage.

The paper published in The Journal of Chemical Thermodynamics describes recovering them from phosphogypsum – waste from phosphoric acid production – as a potential solution. Each year, an estimated 250 million tons of phosphate rock are mined to produce phosphoric acid for fertilizers. The US mined approximately 28 million metric tons in 2017. Rare earth elements generally amount to less than 0.1 percent in phosphate rock. But worldwide, about 100,000 tons of these elements per year end up in phosphogypsum waste. That’s almost as much as the approximately 126,000 tons of rare earth oxides produced worldwide each year.

Conventional methods to extract rare earth elements from ores generate millions of tons of toxic and acidic pollutants. Instead of using harsh chemicals to extract the elements, organic acids produced by bacteria can be used says Paul  Antonick and Zhichao Hu. The explored using mineral and organic acids, including a bio-acid mixture, to extract six rare earth elements (yttrium, cerium, neodymium, samarium, europium and ytterbium) from synthetic phosphogypsum. Scientists led by David Reed at Idaho National Laboratory produced the bio-acid mixture – consisting primarily of gluconic acid, found naturally in fruits and honey – by growing the bacteria Gluconobacter oxydans on glucose. The results suggest that the bio-acid did a better job extracting rare earth elements than pure gluconic acid at the same pH (2.1), or degree of acidity. The mineral acids (sulfuric and phosphoric) failed to extract any rare earth elements in that scenario. When the four

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