ANSTO Helps Develop Novel Thin-Film Technology

ANSTO Helps Develop Novel Thin-Film Technology

A large collaboration of Australian and New Zealand researchers has established that a thin film technology can be used to monitor stormwater effectively and provides a way to translate the presence of metal contaminants into potential risks to aquatic ecosystems. This research was undertaken during a rainstorm in Melbourne and does not apply to catastrophic flood conditions.

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The approach provides a way to assess differences in metals and their behaviour during an entire storm period. The information can support the effective management of aquatic environments that are influenced by short-term, intermittent discharge events.

Dr Sarah McDonald who worked on this project as a PhD candidate from the University of Melbourne stated that they found a link between dissolved metal concentrations in stormwater runoff and the amount of rainfall with the use of diffusive gradients in thin films (DGT) technology. McDonald and associates, including isotopic ecologist Dr Tom Cresswell of ANSTO, reported the findings in a paper in Water Research.

The results of the study indicated that for the stormwater sampled, the dissolved metal concentrations should not pose a risk of adverse effects to most aquatic organisms. The DGT device measures very low concentrations of metals in water using a thin diffusive boundary layer that ensures minimal impact on the precision of the device.

Investigators deployed sets of DGTs at the Moonee Ponds Creek sub-catchment in Melbourne during February and March 2021. They also examined water quality before the storm, during the storm and afterwards as creek levels rose. This was one of the first applications of putting the technology out in a storm and measuring that short term pulse of metals.

The DGTs revealed that the metals were not free and available for biological uptake, but they were bound up in forms less available. ANSTO noted the wide variety of sources of the metals that get transported during a storm. The metals in an urban environment come from lots of different sources including vehicle brake wear, tyre rubber, fuel deposits and other industrial sources and are transported by stormwater.

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Any assessment of urban waterways requires an understanding of the way contaminants are dispersed in the stormwater runoff and the form they take during the event. Urban stormwater contains a diverse range of physical, chemical, and biological contaminants that may decrease water quality.

Positively charged metals, as chemical contaminants, are among the most commonly identified pollutants due to numerous human sources, including metal surfaces from the built environment, industrial runoff and the use of motor vehicles.

Aluminium, cadmium, cobalt, copper, lead, and zinc are the main metal contaminants. Metals can come in a variety of forms, including those that can be absorbed biologically. The bioavailability of metals can be predicted by measuring metal concentrations and their form (or how labile they are). Labile metals can be positively charged and weakly bound inorganic and organometallic complexes.

Computer modelling of the labile metal concentrations indicated high mobility, especially when the initial runoff entered and mixed with the creek. However, this was found to be an underestimate owing to water profiles being quite variable over a relatively short period of time, so the majority of metals tended to be complexed by other constituents in the water, reducing their potential bioavailability.

An approach that provides evidence by measuring labile metal concentrations is important for regulation and management purposes. The method of data collection could be applied to different locations. Scientists are now looking at potentially modifying existing environmental quality guidelines for levels of key labile metal contaminants.