Removing PFAS from public water will cost billions and take time – here are ways to filter out some harmful ‘forever chemicals’ at home
- Written by Kyle Doudrick, Associate Professor of Civil and Environmental Engineering and Earth Sciences, University of Notre Dame
Chemists invented PFAS in the 1930s to make life easier: Nonstick pans, waterproof clothing, grease-resistant food packaging and stain-resistant carpet were all made possible by PFAS. But in recent years, the growing number of health risks found to be connected to these chemicals[1] has become increasingly alarming.
PFAS – perfluoroalkyl and polyfluoroalkyl substances – are now either suspected or known to contribute[2] to thyroid disease, elevated cholesterol, liver damage and cancer[3], among other health issues[4].
They can be found in the blood of most Americans[5] and in many drinking water systems, which is why the Environmental Protection Agency in April 2024 finalized the first enforceable federal limits[6] for six types of PFAS in drinking water systems. The limits – between 4 and 10 parts per trillion for PFOS, PFOA, PFHxS, PFNA and GenX – are less than a drop of water in a thousand Olympic-sized swimming pools, which speaks to the chemicals’ toxicity. The sixth type, PFBS, is regulated as a mixture using what’s known as a hazard index[7].
Meeting these new limits won’t be easy or cheap. And there’s another problem: While PFAS can be filtered out of water, these “forever chemicals” are hard to destroy.
My team[8] at the University of Notre Dame works on solving problems involving contaminants in water systems, including PFAS. We explore new technologies to remove PFAS from drinking water[9] and to handle the PFAS waste[10]. Here’s a glimpse of the magnitude of the challenge and ways you can reduce PFAS in your own drinking water:
Removing PFAS will cost billions per year
Every five years, the EPA is required to choose 30 unregulated contaminants to monitor[11] in public drinking water systems. Right now, 29 of those 30 contaminants are PFAS. The tests provide a sense of just how widespread PFAS are in water systems and where.
The EPA has taken over 22,500 samples from about 3,800 of the 154,000 public drinking water systems in the U.S. In 22% of those water systems, its testing found at least one of the six newly regulated PFAS, and about 16% of the systems exceeded the new standards. East Coast states had the largest percentage of systems with PFAS levels exceeding the new standards in EPA tests conducted so far.
Under the new EPA rules, public water systems have until 2027 to complete monitoring for PFAS and provide publicly available data. If they find PFAS at concentrations that exceed the new limits, then they must install a treatment system by 2029.
How much that will cost public water systems, and ultimately their customers, is still a big unknown, but it won’t be cheap.
The EPA estimated the cost[12] to the nation’s public drinking water systems to comply with the news rules at about US$1.5 billion per year. But other estimates[13] suggest the total costs of testing and cleaning up PFAS contamination will be much higher. The American Water Works Association put the cost at over $3.8 billion per year[14] for PFOS and PFOA alone.
There are more than 5,000 chemicals[15] that are considered PFAS, yet only a few have been studied for their toxicity, and even fewer tested for in drinking water. The United States Geological Survey estimates that nearly half of all tap water[16] is contaminated with PFAS.
Some money for testing and cleanup will come from the federal government[17]. Other funds will come from 3M and DuPont, the leading makers of PFAS. 3M agreed in a settlement to pay between $10.5 billion to $12.5 billion[18] to help reimburse public water systems for some of their PFAS testing and treatment. But public water systems will still bear additional costs, and those costs will be passed on to residents.
Next problem: Disposing of ‘forever chemicals’
Another big question is how to dispose of the captured PFAS once they have been filtered out.
Landfills are being considered, but that just pushes the problem to the next generation. PFAS are known as “forever chemicals” for a reason – they are incredibly resilient and don’t break down naturally, so they are hard to destroy.
Studies have shown that PFAS can be broken down with energy-intensive technologies. But this comes with steep costs. Incinerators must reach over 1,800 degrees Fahrenheit (1,000 Celsius)[19] to destroy PFAS, and the possibility of creating potentially harmful byproducts is not yet well understood[20]. Other suggested techniques, such as supercritical water oxidation[21] or plasma reactors[22], have the same drawbacks.
Paul Bersebach/MediaNews Group/Orange County Register via Getty Images[23]So who is responsible for managing PFAS waste? Ultimately the responsibility will likely fall on public drinking water systems, but the EPA has no waste regulations for PFAS.
Steps to protect your home from PFAS
Your first instinct might be to use bottled water to try to avoid PFAS exposures, but a recent study found that even bottled water[24] can contain these chemicals. And bottled water is regulated by a different federal agency, the Food and Drug Administration, which has no standards for PFAS.
Your best option is to rely on the same technologies that treatment facilities will be using:
Activated carbon is similar to charcoal. Like a sponge, it will capture the PFAS, removing it from the water. This is the same technology in refrigerator filters and in some water pitcher filters, like Brita or PUR. Note that many refrigerator manufacture’s filters are not certified for PFAS, so don’t assume they will remove PFAS to safe levels.
Ion exchange resin is the same technology found in many home water softeners. Like activated carbon, it captures PFAS from the water, and you can find this technology in many pitcher filter products. If you opt for a whole house[25] treatment system, which a plumber can attach where the water enters the house, ion exchange resin is probably the best choice. But it is expensive.
Reverse osmosis is a membrane technology that only allows water and select compounds to pass through the membrane, while PFAS are blocked. This is commonly installed at the kitchen sink and has been found to be very effective[26] at removing most PFAS in water. It is not practical for whole house treatment, but it is likely to remove a lot of other contaminants as well.
If you have a private well instead of a public drinking water system, that doesn’t mean you’re safe from PFAS exposure. Wisconsin’s Department of Natural Resources estimates that 71% of shallow private wells[27] in that state have some level of PFAS contamination. Using a certified laboratory to test well water for PFAS can run $300-$600 per sample, a cost barrier that will leave many private well owners in the dark.
For all the treatment options, make sure the device you choose is certified for PFAS by a reputable testing agency[28], and follow the recommended schedule for maintenance and filter replacement. Unfortunately, there is currently no safe way to dispose of the filters, so they go in the trash. No treatment option is perfect, and none is likely to remove all PFAS down to safe levels, but some treatment is better than none.
References
- ^ health risks found to be connected to these chemicals (theconversation.com)
- ^ known to contribute (doi.org)
- ^ and cancer (dceg.cancer.gov)
- ^ among other health issues (doi.org)
- ^ most Americans (doi.org)
- ^ first enforceable federal limits (www.epa.gov)
- ^ hazard index (www.epa.gov)
- ^ My team (www.doudrick.info)
- ^ drinking water (doi.org)
- ^ handle the PFAS waste (serdp-estcp.mil)
- ^ unregulated contaminants to monitor (www.epa.gov)
- ^ EPA estimated the cost (www.epa.gov)
- ^ other estimates (news.bloomberglaw.com)
- ^ over $3.8 billion per year (www.awwa.org)
- ^ There are more than 5,000 chemicals (www.niehs.nih.gov)
- ^ nearly half of all tap water (www.usgs.gov)
- ^ will come from the federal government (news.bloomberglaw.com)
- ^ between $10.5 billion to $12.5 billion (apnews.com)
- ^ over 1,800 degrees Fahrenheit (1,000 Celsius) (www.regulations.gov)
- ^ not yet well understood (www.epa.gov)
- ^ supercritical water oxidation (doi.org)
- ^ plasma reactors (www.af.mil)
- ^ Paul Bersebach/MediaNews Group/Orange County Register via Getty Images (www.gettyimages.com)
- ^ even bottled water (www.consumerreports.org)
- ^ whole house (uswatersystems.com)
- ^ found to be very effective (nicholas.duke.edu)
- ^ 71% of shallow private wells (www.wpr.org)
- ^ by a reputable testing agency (www.nsf.org)
Authors: Kyle Doudrick, Associate Professor of Civil and Environmental Engineering and Earth Sciences, University of Notre Dame