Rare earth metals such as cerium and gadolinium are increasingly entering wastewater from industry, but also from hospitals. This is shown by Eawag’s investigations at 63 wastewater treatment plants in Switzerland.
Today, almost nothing works without rare earth metals. There would be no smartphones, flat screens, LED lamps, rechargeable batteries, electric motors and many other electronic devices. In the high-tech industry, for example in the automotive, electronics and energy sectors and in medicine, it is impossible to imagine life without these valuable raw materials. It is therefore of increasing interest to know where these rare earth metals disappear to after use.
On behalf of the Federal Office of the Environment FOEN, the aquatic research institute Eawag has now for the first time taken a closer look at rare earth elements in Swiss wastewater. A team of researchers from the two departments of Process Engineering and Water Resources and Drinking Water investigated the sewage sludge from 63 Swiss wastewater treatment plants (WWTPs). The most important thing first is that rare earth metals, which are used in industry and hospitals, often end up in wastewater.
The challenge: Distinguishing between natural and human sources
First, the research team estimated what proportion of the rare earth metals came from natural sources. This is the only way to assess what proportion is added by humans. To do this, the researchers analysed soil samples from Switzerland, taking into account the PAAS values (post-Achaean Australian shales), which reflect the average composition of rare earth elements in the earth’s crust. This is how they obtained the naturally occurring composition of the rare earth elements in Switzerland - the background measurement. In addition, the research team developed two new methods to deduce the proportions from industrial sources from the concentrations measured in the wastewater and the natural sample.
The findings: in the sewage sludge of most WWTPs, the concentrations of rare earth elements found correspond to the natural background measurement. However, in a few WWTPs, particularly those of Yverdon, Bioggio, Hofen and Thal, the concentrations of individual rare earth metals were significantly higher. The research team concluded that rare earth metals are not used on a large scale, but come from highly-specialised applications in industry.
The highest concentrations were found for the rare earth cerium. Cerium is often used as an abrasive in industry. Extrapolated for Switzerland, more than 4,000 kilograms of cerium reach the WWTPs every year, around half of which comes from industrial applications. A very large proportion of this remains in the sewage sludge, around 95 percent. The rest ends up in the environment. The researchers therefore assume that elevated cerium concentrations will also be found in lakes, rivers and groundwater in the near future.
Gadolinium is a special case. Elevated concentrations were already detected in water bodies in Europe 20 years ago. The source was assumed to be the wastewater from hospitals. In the current Eawag study, the researchers found around 80 percent of the total gadolinium content originating from industrial sources in the Ramsen WWTP near Lake Constance on the German-Swiss border. The WWTP treats wastewater from the town of Singen in Germany, where a cancer centre with MRI facilities is located. The region is also home to industries that produce large quantities of gadolinium-based contrast agents. The findings therefore confirm the previous assumption that the gadolinium found in sewage sludge can be traced back to the production and use of contrast agents. Appropriate measures to reduce the input of industrial gadolinium into wastewater by industry have already been taken and will lead to a significant reduction in the gadolinium load.
Unlike the other rare earth elements, the concentration of lanthanum is elevated in the sewage sludge of all WWTPs investigated. One possible cause could be biological processes that alter the retention of lanthanum in sewage sludge. Another explanation could be the use of lanthanum-enriched fertilisers in agriculture. However, the extent to which biological processes or fertilisers are responsible for the increased values needs to be investigated in more detail.
Ralf Kaegi, Alexander Gogos, Andreas Voegelin, Stephan J. Hug, Lenny H.E. Winkel, Andreas M. Buser, Michael Berg: Quantification of individual Rare Earth Elements from industrial sources in sewage sludge. Water Research X.