News: Big Impact, Innovation, News, Research, SA

Using waste to clean the planet

Researchers at Flinders University are turning by-products of the petroleum industry and waste cooking oil into a tool for resource recovery and environmental decontamination.

Download the flyer

CHALLENGE

Environments polluted by mercury and other heavy metals, oil spills and toxic chemicals such as PFAS cause untold damage to health, habitats, and animal and plant life and prevent the productive use of the contaminated land. This pollution can result from mining operations, energy production, industrial effluent, oil extraction and transport, and fire-fighting operations.

For example, the negative impact of environmental mercury on children’s brain development is costly. It is estimated at $8.7 billion annually in the USA, and €9 billion annually in the EU. Oil spills are another major global issue, with around 7000 tonnes of crude oil spilling from tankers into oceans in 2017 alone. The explosion on the Deepwater Horizon offshore drilling rig in 2010 led to the release of approximately 4.9 million barrels of crude oil into the Gulf of Mexico. Cost-efficient remediation of contaminated environments is a priority.

RESEARCH

Polymers developed at Flinders University by A/Prof. Justin Chalker and his team, made from industrial waste materials sulfur and used cooking oil, have been shown in successful field trials to securely bind toxic forms of mercury and remove it from the environment. These polymers also soak up oil like a sponge, allowing oil spills to be removed from water, the oil recovered, and the polymer regenerated for further use.

A demonstration of how the polymer sponge absorbs oil but resists water

Tests of another non-toxic variation of this patented polymer recently showed it can absorb PFAS contaminants from water at the contaminated Edinburgh air base. There are also additional applications in residue-free slow-release fertilisers.

The team used scanning electron microscopy and energy-dispersive X-ray spectroscopy at Microscopy Australia’s Flinders University facility, Flinders Microscopy and Microanalysis, to reveal both the structure and elemental make-up of the polymer. This aided in the design of the polymers and in understanding their properties. Raman spectroscopy at the Australian National Fabrication Facility, a fellow NCRIS facility at Flinders University, was used to confirm that oil “sticks” to the polymer.

False coloured scanning electron micrograph of PFAS droplets (green) adsorbed by the polymer sponge (brown)

IMPACT

The patents for these polymers were recently bought by Singapore-based company, Clean Earth Technologies (CET). The deal also provides ongoing funding for collaboration with the Flinders team.

CET plan to manufacture the polysulfide at a plant in Adelaide. Manufacturing of the production equipment for the plant is also being undertaken locally, creating jobs and boosting the economy.

The polysulfide can be synthesised on a large scale, for cost-effective: 

  • removal and recovery of mercury and other heavy metals from the environment
  • removal of PFAS contamination
  • removal and recovery of spilled oil from oceans and beaches
  • recovery of useful heavy-metal catalysts 

leading to smarter, healthier populations and cleaner, safer environments.

A demonstration of how the polymer sponge adsorbs oil

Ref: A. D. Tikoalu et al., 2020, Advanced Sustainable Systems DOI: 10.1002/adsu.201900111

A mercury contaminated landscape

September 22, 2020