Photochemical Production of Carbon Monoxide from Dissolved Organic Matter: Role of Lignin Methoxyarene Functional Groups
| Autor: | Rachele Ossola, Richard Gruseck, Joanna Houska, Alessandro Manfrin, Morgan Vallieres, Kristopher McNeill |
|---|---|
| Jazyk: | angličtina |
| Rok vydání: | 2022 |
| Předmět: |
allyl alcohol
dissolved organic matter photodegradation lignin mechanism carbon cycling Dissolved Organic Matter carbon monoxide quantum yield spectra Formaldehyde Environmental Chemistry methanol Photolysis model hydroxyl radicals hydrogen-peroxide aqueous-solutions General Chemistry Carbon Dioxide Oxidants Photochemical Processes rate constants center-dot methoxy-substituted aromatics reaction mechanism photoproduction |
| Zdroj: | Environmental Science & Technology, 56 (18) |
| ISSN: | 0013-936X 1520-5851 |
| Popis: | Carbon monoxide (CO) is the second most abundant identified product of dissolved organic matter (DOM) photodegradation after CO2, but its formation mechanism remains unknown. Previous work showed that aqueous photodegradation of methoxy-substituted aromatics (ArOCH3) produces CO considerably more efficiently than aromatic carbonyls. Following on this precedent, we propose that the methoxy aromatic groups of lignin act as the C source for the photochemical formation of CO from terrestrial DOM via a two-step pathway: formal hydrolytic demethylation to methanol and methanol oxidation to CO. To test the reasonableness of this mechanism, we investigated the photochemistry of eight lignin model compounds. We first observed that initial CO production rates are positively correlated with initial substrate degradation rates only for models containing at least one ArOCH3 group, regardless of other structural features. We then confirmed that all ArOCH3-containing substrates undergo formal hydrolytic demethylation by detecting methanol and the corresponding phenolic transformation products. Finally, we showed that hydroxyl radicals, likely oxidants to initiate methanol oxidation to CO, form during irradiation of all models. This work proposes an explicit mechanism linking ubiquitous, abundant, and easily quantifiable DOM functionalities to CO photoproduction. Our results further hint that methanol may be an abundant (yet overlooked) DOM photoproduct and a likely precursor of formaldehyde, formic acid, and CO2 and that lignin photodegradation may represent a source of hydroxyl radicals. Environmental Science & Technology, 56 (18) ISSN:0013-936X ISSN:1520-5851 |
| Databáze: | OpenAIRE |
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