Photo-production of excited triplet-state of dissolved organic matters in inland freshwater and coastal seawater

•fTMP are higher in coastal seawater than in inland freshwater.•Proportion of high-energy 3DOM* varies greatly in coastal seawater.•fTMP estimation models are available for both freshwater and seawater.•E2:E3 is more reliable than spectral slopes for modeling fTMP.•Different freshwater catchment cha...

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Veröffentlicht in:Water research (Oxford) 2024-04, Vol.253, p.121260-121260, Article 121260
Hauptverfasser: Guo, Zhongyu, Wang, Tingting, Ichiyanagi, Hidetaka, Ateia, Mohamed, Chen, Guo, Wang, Jieqiong, Fujii, Manabu, En, Kaichii, Li, Tiansheng, Sohrin, Rumi, Yoshimura, Chihiro
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Sprache:eng
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Zusammenfassung:•fTMP are higher in coastal seawater than in inland freshwater.•Proportion of high-energy 3DOM* varies greatly in coastal seawater.•fTMP estimation models are available for both freshwater and seawater.•E2:E3 is more reliable than spectral slopes for modeling fTMP.•Different freshwater catchment characteristics affect fTMP. The excited triplet-state of dissolved organic matter (3DOM*) is a major reactive intermediate in sunlit waters. Its quantum yield is important in understanding the fate of organic micropollutants. The degradation efficiency of its chemical probe, 2,4,6-trimeythlphenol (fTMP), is generally used as a proxy of the quantum yield. However, fTMP has been described and modelled only for freshwater systems. Therefore, this study quantified fTMP in inland freshwater and coastal seawater sampled in Japan by conducting steady-state photochemical experiments. Optical properties of water were then used to model fTMP. Results indicated that the inland freshwater DOM originated mainly from terrestrial sources, while the coastal seawater DOM were microbial-dominated. On average, inland freshwater exhibited lower fTMP (61.2 M−1) than coastal seawater (79.7 M−1) and the coastal seawater exhibited significant variations in the proportion of high-energy 3DOM* (> 250 kJ/mol). In addition, E2:E3 (ratio of absorbance at 254 to 365 nm) was positively correlated with fTMP of inland freshwater, coastal seawater, and the overall dataset. Catchment conditions such as forest coverage also influenced the production of 3DOM* and high-energy 3DOM* in inland freshwater. Furthermore, the developed models estimated fTMP based on the optical properties of both freshwater and seawater, providing valuable insights about 3DOM* photochemistry in the aquatic environment. [Display omitted]
ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2024.121260