2006
DOI: 10.1021/es0520767
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Atmospheric Chemistry ofN-methyl Perfluorobutane Sulfonamidoethanol, C4F9SO2N(CH3)CH2CH2OH:  Kinetics and Mechanism of Reaction with OH

Abstract: Relative rate methods were used to measure the gas-phase reaction of N-methyl perfluorobutane sulfonamidoethanol (NMeFBSE) with OH radicals, giving k(OH + NMeFBSE) = (5.8 +/- 0.8) x 10(-12) cm3 molecule(-1) s(-1) in 750 Torr of air diluent at 296 K. The atmospheric lifetime of NMeFBSE is determined by reaction with OH radicals and is approximately 2 days. Degradation products were identified by in situ FTIR spectroscopy and offline GC-MS and LC-MS/MS analysis. The primary carbonyl product C4F9SO2N(CH3)CH2CHO, … Show more

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Cited by 292 publications
(289 citation statements)
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“…In principle, gaseous FASEs likely react with OH radicals resulting in various products, including FASAs. It was reported that the atmospheric lifetime of MeFBSE is approximately 2 days, and MeFBSA has an atmospheric lifetime of >20 days (D'Eon et al 2006). In this work, we did not find a significant change of composition between FASAs and FASEs as compared to the data determined in an urban area of Hamburg (Germany) (Dreyer and Ebinghaus 2009).…”
Section: Resultscontrasting
confidence: 49%
See 1 more Smart Citation
“…In principle, gaseous FASEs likely react with OH radicals resulting in various products, including FASAs. It was reported that the atmospheric lifetime of MeFBSE is approximately 2 days, and MeFBSA has an atmospheric lifetime of >20 days (D'Eon et al 2006). In this work, we did not find a significant change of composition between FASAs and FASEs as compared to the data determined in an urban area of Hamburg (Germany) (Dreyer and Ebinghaus 2009).…”
Section: Resultscontrasting
confidence: 49%
“…Because of their slow reaction process with hydroxyl radicals, atmospheric lifetimes were estimated~10−20 days for FTOH and~20−50 days for perfluoroalkane sulphonamide (FASA) in smog chamber studies (Ellis et al 2004;Martin et al 2006) and atmospheric residence time of more than 50 days for FTOHs in field studies (Piekarz et al 2007), which suggest they are subject to regional and long-range atmospheric transport, e.g., the Arctic and Antarctic (Dreyer et al 2009b;Stock et al 2007;Jahnke et al 2007b). Degradation of these precursors may account for the presence of PFOA and PFOS in remote regions (Andersen et al 2005;D'Eon et al 2006;Ellis et al 2004;Martin et al 2006;Zhao et al 2012). Apart from atmospheric reaction, degradation of FTOHs and FTSEs/FOSAs in the aquatic phase can be an additional source for PFCAs and PFSAs, especially in the remote oceans (Armitage et al 2006(Armitage et al , 2009Cousins et al 2011).…”
Section: Introductionmentioning
confidence: 99%
“…The dominance of PFOA and PFOS in coastal waters might indicate that the contamination originated from WWTP effluents where they were found to be the predominant PFCs, such as in Denmark (Bossi et al, 2008), Georgia and Kentucky (USA) (Loganathan et al, 2007), Germany (Ahrens et al, 2009c), Canada (Furdui et al, 2008), Austria (Clara et al, 2008) and Catalonia (Sánchez-Avila et al, 2010). In our study, the concentration of PFBS (average of 302 pg/L) was about one order of magnitude higher than that of PFOS (average of 24 pg/L), This can be partly attributed to the increasing production of N-methyl perfluorobutane sulfonamidoethanol (MeFBSE) and related products with four perfluorinated carbons, which was introduced after the voluntary phase-out of POSF by the 3M Company in 2000 (D'Eon et al, 2006). Our results indicate that the emissions of PFOS into the aqueous environment decreased whereas the C 4 -based compounds PFBS became the predominant PFSA.…”
Section: Identification Of Sources Of Individual Pfcsmentioning
confidence: 60%
“…In contrast, PFOS is the predominant compound in wildlife (Kannan et al, 2001a,b), which can be explained by its higher bioaccumulation potential, whereas PFOA has a higher water solubility (Brooke et al, 2004) and lower sorption potential to sediment . On the other hand, the PFOA concentrations are usually higher in open-ocean waters compared to PFOS, which can be explained by different amount of discharge into the aqueous environment, different sources Paul et al, 2009), different degradation process of the precursors D'Eon et al, 2006) and different physico-chemical characteristics.…”
Section: Identification Of Sources Of Individual Pfcsmentioning
confidence: 99%
“…The mean concentration of the ∑ FASAs was 4.4 ± 2.6 pg/m 3 , which was significantly higher than that of the ∑ FASEs (mean 0.61 ± 0.39 pg/m 3 ). FASAs last longer in air than FASEs and have the potential to be transported across longer distances than FASEs (D'Eon et al, 2006). MeFBSA and MeFBSE were detected in all samples, and showed higher concentrations than those of MeFOSA and Me/EtFOSE, which may be attributed to the replacement of C 8 -PFASs (Lai et al, 2016).…”
Section: Resultsmentioning
confidence: 84%