Scientists at Deakin University and Spain’s Tecnalia research and innovation hub have improved the process for recovering rare earth metals, which are essential in mobile phones and other modern technologies such as hybrid-electric vehicles.
Deakin Institute for Frontier Materials (IFM) researcher Dr Cristina Pozo-Gonzalo, who leads the electro-materials project, said there was an urgent need to develop a cleaner and simpler process for recovering rare earth materials, as current extraction methods generated huge amounts of toxic and radioactive waste.
“Consumption of REMs has been gradually increasing since the 1960s due to their use in electronics, optics and magnetics, making them ubiquitous in everyday applications such as television screens and computer systems,” Pozo-Gonzalo said.
“They’re also a key component of many modern technologies, including hard disk drives, clean technologies such as wind power turbines and batteries for hybrid-electric vehicles.”
Pozo-Gonzalo said that increased demand for rare earth materials – which include elements such as cerium, praseodymium, neodymium and lanthanum – was creating pressure on global supply-chains.
“To add to concerns, almost 85 per cent of the world’s rare earth metals’ primary resource are in China, where their government has restricted exports for periods of time in the recent past, endangering availability and price stability,” Pozo-Gonzalo added.
“There’s growing concern that future access to these materials won’t be reliable, leading to them being targeted for reclamation and recycling. The primary extraction and processing methods for rare earth materials are also energy-intensive processes that lead to the excessive generation of toxic and radioactive waste. We need a real alternative.
“After separating the metals from their end-of-life product, our team uses advanced electrolytes known as ionic liquids (liquid salt-based systems) to recover the rare earth metals from the resulting solution using a process of electro-deposition – when you use a low electric current to cause metals to reform and deposit on a desired surface.
“This new method for recovering rare earth metals has great potential and minimises the generation of toxic and harmful waste. We are also aiming for a method that can easily be implemented widely across the world.”
According to Pozo-Gonzalo, rare earth metals were among the top critical raw materials identified by the European Commission, Geoscience Australia and United States Department of Energy.
“The efficient recovery of rare earth metals from recycled materials is becoming increasingly important, given that only about three to seven per cent of rare earth metals are currently recovered from end-products because of technological difficulties,” Pozo-Gonzalo said.
“Our work addresses a key knowledge gap in the rare earth metal recycling process and is an important early step towards establishing a clean and sustainable processing route for rare earth metals and alleviating the current pressures on these critical elements.”
The project is a collaboration between Deakin IFM researchers Pozo-Gonzalo, professor Maria Forsyth, associate professor Jennifer Pringle, and Dr Matthias Hilder, and Tecnalia Research and Innovation researchers Laura Sanchez-Cupido, Amal Siriwardana and Ainhoa Unzurrunzaga.
Their full findings, Water-Facilitated Electrodeposition of Neodymium in a Phosphonium-Based Ionic Liquid, have not been published in the Journal of Physical Chemistry Letters.