Lithium’s high reactivity can cause trouble in batteries based on lithium-metal anodes. The metal degrades the fluorinated electrolytes used in these batteries, affecting performance. Because these electrolytes contain fluorine, as do PFAS, the harmful per- and polyfluoroalkyl substances that persist in the environment, Chibueze Amanchukwu says he and his colleagues at the University of Chicago wondered “can we take that disadvantage of a lithium-metal battery and apply it to PFAS destruction?”The researchers tested their hunch by dissolving PFAS in the electrolyte solution of a lithium-containing electrochemical cell. They found that lithium indeed helps break 95% of the strong carbon-fluorine bonds in perfluorooctanoic acid (PFOA), a common PFAS (Nat. Chem. 2026, DOI: 10.1038/s41557-025-02057-7). Instead of chopping up PFOA into smaller PFAS with shorter carbon chains, the lithium-based method breaks it down completely to lithium fluoride. The researchers reused the fluoride to make non-PFAS compounds relevant for batteries and pharmaceuticals. The team showed that the method also works to various extents on 33 other such compounds.Most electrochemical techniques for PFAS destruction rely on oxidation: taking away electrons to break the C–F bonds. Oxidation currently works better in the aqueous conditions for which these methods have been developed, Amanchukwu says. If you try reduction—lobbing electrons at the compound to make them unstable so they fall apart—the method tends to fail. Instead of destroying PFAS, the electrons usually end up reducing water to form hydrogen.But reducing fluorine is simpler, Amanchukwu says. “It is the most electronegative element, so giving it electrons is easier.” That’s
Prachi Patel (Mon,) studied this question.