Researchers track PFAS, microplastics from landfills to treatment plants

Scientists analyzed the liquid waste, or leachate, released by four Illinois landfills and the inflows and outflows of associated wastewater treatment plants to determine the fate of two contaminants: microplastics and per- and polyfluoroalkyl substances, or PFAS.

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November 19, 2024 This article has been reviewed according to Science X's editorial process and policies . Editors have highlightedthe following attributes while ensuring the content's credibility: fact-checked peer-reviewed publication trusted source proofread by Diana Yates, University of Illinois at Urbana-Champaign Scientists analyzed the liquid waste, or leachate, released by four Illinois landfills and the inflows and outflows of associated wastewater treatment plants to determine the fate of two contaminants: microplastics and per- and polyfluoroalkyl substances, or PFAS. The good news from the study is that landfills retain most of the plastic waste that is dumped there, and wastewater treatment plants remove 99% of the microplastics and some of the PFAS from the wastewater and landfill leachate they take in.

The bad news is that both microplastics and PFAS accumulate in the biosolids that settle to the bottom of wastewater treatment plants. These biosolids must be disposed of in other ways. The findings are published in the journal Science of the Total Environment .



According to the industry-funded National Biosolids Data Project, 70% of the biosolids from Illinois wastewater treatment plants are used as fertilizers on agricultural land , and 30% are buried in landfills. This means that most of the microplastics and PFAS that flow into wastewater treatment plants are going right back into the environment, said John Scott, a research scientist at the Illinois Sustainable Technology Center at the University of Illinois Urbana-Champaign who led the study with fellow ISTC research scientist Andres Prada. "The wastewater treatment plants are just taking the contaminants from one media and putting it into another," Scott said.

Several hundred million tons of plastics are produced each year globally, and an estimated 79% of this material ends up in landfills or "becomes fugitive in the environment," the researchers wrote in their report. Both microplastics and the endocrine-disrupting chemicals known as PFAS are now ubiquitous: detected in soil, water and in the human body, they said. The new study is unusual in that it calculated the mass of microplastics in landfill leachate and wastewater influent and effluent.

Most studies simply count the number of microplastic particles per volume of liquid, an unreliable measure because the particles will keep breaking into smaller bits, Prada said. To get the mass, the team measured the total surface area of the plastic particles and incorporated a standard measure of thickness and density based on the most common microplastic waste types: polyethylene and polypropylene. "Landfills and wastewater treatment plants are usually studied separately, but in reality, those are combined systems," Prada said.

"Regulations require that landfills send their liquid waste to the treatment plants." And many studies look at only one contaminant at a time, he said. "We wanted to put everything together, look at both systems and give results for both contaminants," Prada said.

The analysis revealed that while landfills do a good job of retaining microplastics, their leachate contains high levels of PFAS. Discover the latest in science, tech, and space with over 100,000 subscribers who rely on Phys.org for daily insights.

Sign up for our free newsletter and get updates on breakthroughs, innovations, and research that matter— daily or weekly . "We were surprised how high the PFAS levels were in landfill leachate, while the microplastics were lower than expected," Prada said. While plastics degrade more slowly in landfills due to the compression of waste and the lack of solar radiation once they're buried, the plastics will continue to break down into smaller particles, which will eventually flow out with the leachate, Scott said.

Wastewater treatment plants are designed to take in thousands of gallons of wastewater from sanitary and storm sewer systems, and that water also carries a significant load of microplastics and PFAS. While the concentration of PFAS in water flowing through these systems is lower than that found in landfill leachate, the massive volume of water coming in from sewers brings in a higher overall load of both contaminants, the team reported. Wastewater treatment plants can take in 10,000 gallons of wastewater per minute but only about 30,000 gallons of landfill leachate per day, Prada said.

The problem of microplastics and PFAS in biosolids is not easy to solve, the researchers said. Spreading PFAS and microplastics across cropland is not a good practice, Scott said. "But what else are we to do with it? If we landfill it, we're just going around and around in the circle of moving it from landfill to wastewater treatment plant and back to the landfill.

" Trying to treat the biosolids before disposal is a very expensive prospect, Scott said. The best practice would be to prevent the problem of plastic and PFAS pollution further upstream, he said. "It's time to tell people to start moving away from these things, stop producing these things," Scott said.

"Let's turn them off at the tap before this gets any worse." More information: Andres F. Prada et al, Microplastics and per- and polyfluoroalkyl substances (PFAS) in landfill-wastewater treatment systems: A field study, Science of The Total Environment (2024).

DOI: 10.1016/j.scitotenv.

2024.176751 Journal information: Science of the Total Environment Provided by University of Illinois at Urbana-Champaign.