Comparing the leaching behavior of per- and polyfluoroalkyl substances from contaminated soils using static and column leaching tests
Date
2021
Authors
Kabiri, S.
Tucker, W.
Navarro, D.A.
Bräunig, J.
Thompson, K.
Knight, E.R.
Nguyen, T.M.H.
Grimison, C.
Barnes, C.M.
Higgins, C.P.
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Journal article
Citation
Environmental Science and Technology, 2021; 56(1):368-378
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Shervin Kabiri, William Tucker, Divina A. Navarro, Jennifer Bräunig, Kristie Thompson, Emma R. Knight, Thi Minh Hong Nguyen, Charles Grimison, Craig M. Barnes, Christopher P. Higgins, Jochen F. Mueller, Rai S. Kookana, and Michael J. McLaughlin
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Abstract
Soil contaminated with aqueous film-forming foams (AFFFs) containing per- and polyfluoroalkyl substances (PFASs) at firefighting training sites has become a major concern worldwide. To date, most studies have focused on assessing soil-water partitioning behavior of PFASs and the key factors that can affect their sorption, whereas PFASs leaching from contaminated soils have not yet been widely investigated. This study evaluated the leaching and desorption of a wide range of PFASs from twelve contaminated soils using the Australian Standard Leaching Procedure (ASLP), the U.S. EPA Multiple Extraction Procedure (MEP), and Leaching Environmental Assessment Framework (LEAF). All three leaching tests provided a similar assessment of PFAS leaching behavior. Leaching of PFASs from soils was related to C-chain lengths and their functional head groups. While short-chain (CF2 ≤ 6) PFASs were easily desorbed and leached, long-chain PFASs were more difficult to desorb. PFASs with a carboxylate head group were leached more readily and to a greater extent than those with a sulfonate or sulfonamide head group. Leaching of long-chain PFASs was pH-dependent where leaching increased at high pH, while leaching of short-chain PFASs was less sensitive to pH. Comparing different leaching tests showed that the results using the alkaline ASLP were similar to the cumulative MEP data and the former might be more practical for routine use than the MEP. No single soil property was adequately able to describe PFAS leaching from the soils. Overall, the PFAS chemical structure appeared to have a greater effect on PFAS leaching from soil than soil physicochemical properties.
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© 2021 American Chemical Society