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W2593133043 endingPage "9977" @default.
W2593133043 startingPage "9965" @default.
W2593133043 abstract "Abstract. When hydrocarbons (HCs) are atmospherically oxidized, they form particulate oxidizers, including quinones, organic hydroperoxides, and peroxyacyl nitrates (PANs). These particulate oxidizers can modify cellular materials (e.g., proteins and enzymes) and adversely modulate cell functions. In this study, the contribution of particulate oxidizers in secondary organic aerosols (SOAs) to the oxidative potential was investigated. SOAs were generated from the photooxidation of toluene, 1,3,5-trimethylbenzene, isoprene, and α-pinene under varied NOx levels. Oxidative potential was determined from the typical mass-normalized consumption rate (reaction time t = 30 min) of dithiothreitol (DTTt), a surrogate for biological reducing agents. Under high-NOx conditions, the DTTt of toluene SOA was 2–5 times higher than that of the other types of SOA. Isoprene DTTt significantly decreased with increasing NOx (up to 69 % reduction by changing the HC ∕ NOx ratio from 30 to 5). The DTTt of 1,3,5-trimethylbenzene and α-pinene SOA was insensitive to NOx under the experimental conditions of this study. The significance of quinones to the oxidative potential of SOA was tested through the enhancement of DTT consumption in the presence of 2,4-dimethylimidazole, a co-catalyst for the redox cycling of quinones; however, no significant effect of 2,4-dimethylimidazole on modulation of DTT consumption was observed for all SOA, suggesting that a negligible amount of quinones was present in the SOA of this study. For toluene and isoprene, mass-normalized DTT consumption (DTTm) was determined over an extended period of reaction time (t = 2 h) to quantify their maximum capacity to consume DTT. The total quantities of PANs and organic hydroperoxides in toluene SOA and isoprene SOA were also measured using the Griess assay and the 4-nitrophenylboronic acid assay, respectively. Under the NOx conditions (HC ∕ NOx ratio: 5–36 ppbC ppb−1) applied in this study, the amount of organic hydroperoxides was substantial, while PANs were found to be insignificant for both SOAs. Isoprene DTTm was almost exclusively attributable to organic hydroperoxides, while toluene DTTm was partially attributable to organic hydroperoxides. The DTT assay results of the model compound study suggested that electron-deficient alkenes, which are abundant in toluene SOA, could also modulate DTTm." @default.
W2593133043 created "2017-03-16" @default.
W2593133043 creator A5015582676 @default.
W2593133043 creator A5019206517 @default.
W2593133043 creator A5066607704 @default.
W2593133043 date "2017-08-25" @default.
W2593133043 modified "2023-10-18" @default.
W2593133043 title "Dithiothreitol activity by particulate oxidizers of SOA produced from photooxidation of hydrocarbons under varied NO<sub><i>x</i></sub> levels" @default.
W2593133043 cites W1564094774 @default.
W2593133043 cites W1590198750 @default.
W2593133043 cites W1606404049 @default.
W2593133043 cites W1631968555 @default.
W2593133043 cites W1785546977 @default.
W2593133043 cites W1790299117 @default.
W2593133043 cites W1964891414 @default.
W2593133043 cites W1965087471 @default.
W2593133043 cites W1968237854 @default.
W2593133043 cites W1971239028 @default.
W2593133043 cites W1976459269 @default.
W2593133043 cites W1978848700 @default.
W2593133043 cites W1988591536 @default.
W2593133043 cites W2000790080 @default.
W2593133043 cites W2002570697 @default.
W2593133043 cites W2003286874 @default.
W2593133043 cites W2009833363 @default.
W2593133043 cites W2014050379 @default.
W2593133043 cites W2014799094 @default.
W2593133043 cites W2016363836 @default.
W2593133043 cites W2017337210 @default.
W2593133043 cites W2017741142 @default.
W2593133043 cites W2023412782 @default.
W2593133043 cites W2028021822 @default.
W2593133043 cites W2035014908 @default.
W2593133043 cites W2045747043 @default.
W2593133043 cites W2050999849 @default.
W2593133043 cites W2056017024 @default.
W2593133043 cites W2057152777 @default.
W2593133043 cites W2057537098 @default.
W2593133043 cites W2058952435 @default.
W2593133043 cites W2061699184 @default.
W2593133043 cites W2065785020 @default.
W2593133043 cites W2066367792 @default.
W2593133043 cites W2076094312 @default.
W2593133043 cites W2080483623 @default.
W2593133043 cites W2081874232 @default.
W2593133043 cites W2086579338 @default.
W2593133043 cites W2088780245 @default.
W2593133043 cites W2091943377 @default.
W2593133043 cites W2092850740 @default.
W2593133043 cites W2096689794 @default.
W2593133043 cites W2103374565 @default.
W2593133043 cites W2109285741 @default.
W2593133043 cites W2116507044 @default.
W2593133043 cites W2119310224 @default.
W2593133043 cites W2122966070 @default.
W2593133043 cites W2124610638 @default.
W2593133043 cites W2127510753 @default.
W2593133043 cites W2127814074 @default.
W2593133043 cites W2133757575 @default.
W2593133043 cites W2135707027 @default.
W2593133043 cites W2142912905 @default.
W2593133043 cites W2143965493 @default.
W2593133043 cites W2145180842 @default.
W2593133043 cites W2150751323 @default.
W2593133043 cites W2150956567 @default.
W2593133043 cites W2157530259 @default.
W2593133043 cites W2159409501 @default.
W2593133043 cites W2159735164 @default.
W2593133043 cites W2164840653 @default.
W2593133043 cites W2224368094 @default.
W2593133043 cites W2285911728 @default.
W2593133043 cites W2315670152 @default.
W2593133043 cites W2322662252 @default.
W2593133043 cites W2325021767 @default.
W2593133043 cites W2418729164 @default.
W2593133043 cites W2489678217 @default.
W2593133043 cites W2528073560 @default.
W2593133043 cites W4231891919 @default.
W2593133043 cites W4236028544 @default.
W2593133043 cites W4296234183 @default.
W2593133043 doi "https://doi.org/10.5194/acp-17-9965-2017" @default.
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