Per- and polyfluoroalkyl chemicals, known commonly as PFAS or “forever chemicals,” could take over 40 years to flush out of contaminated groundwater in North Carolina’s Cumberland and Bladen counties, according to a new study.
The study used a new combination of data on PFAS, groundwater age-dating tracers, and groundwater flux to forecast PFAS concentrations in groundwater discharging to tributaries of the Cape Fear River in North Carolina.
The researchers sampled groundwater in two different watersheds adjacent to the Fayetteville Works fluorochemical plant in Bladen County.
“There’s a huge area of PFAS contaminated groundwater—including residential and agricultural land—which impacts the population in two ways,” says David Genereux, professor of marine, earth, and atmospheric sciences at North Carolina State University and leader of the study.
“First, there are over 7,000 private wells whose users are directly affected by the contamination. Second, groundwater carrying PFAS discharges into tributaries of the Cape Fear River, which affects downstream users of river water in and near Wilmington.”
The researchers tested the samples they took to determine PFAS types and levels, then used groundwater age-dating tracers, coupled with atmospheric contamination data from the NC Department of Environmental Quality and the rate of groundwater flow, to create a model that estimated both past and future PFAS concentrations in the groundwater discharging to tributary streams.
They detected PFAS in groundwater up to 43 years old, and concentrations of the two most commonly found PFAS—hexafluoropropylene oxide-dimer acid (HFPO−DA) and perfluoro-2-methoxypropanoic acid (PMPA)—averaged 229 and 498 nanograms per liter (ng/L), respectively.
For comparison, the maximum contaminant level (MCL) issued by the US Environmental Protection Agency for HFPO-DA in public drinking water is 10 ng/L. MCLs are enforceable drinking water standards.
“These results suggest it could take decades for natural groundwater flow to flush out groundwater PFAS still present from the ‘high emission years,’ roughly the period between 1980 and 2019,” Genereux says.
“And this could be an underestimate; the time scale could be longer if PFAS is diffusing into and out of low-permeability zones (clay layers and lenses) below the water table.”
The researchers point out that although air emissions of PFAS are substantially lower now than they were prior to 2019, they are not zero, so some atmospheric deposition of PFAS seems likely to continue to feed into the groundwater.
“Even a best-case scenario—without further atmospheric deposition—would mean that PFAS emitted in past decades will slowly flush from groundwater to surface water for about 40 more years,” Genereux says.
“We expect groundwater PFAS contamination to be a multi-decade problem, and our work puts some specific numbers behind that. We plan to build on this work by modeling future PFAS at individual drinking water wells and working with toxicologists to relate past PFAS levels at wells to observable health outcomes.”
The study appears in Environmental Science & Technology and was supported by the North Carolina Collaboratory.
Additional researchers from NC State, the University of Utah, and the University of Nebraska contributed to the work.
Source: North Carolina State University