Methanediol from cloud-processed formaldehyde is only a minor source of atmospheric formic acid

Atmospheric formic acid is severely underpredicted by models. A recent study proposed that this discrepancy can be resolved by abundant formic acid production from the reaction (1) between hydroxyl radical and methanediol derived from in-cloud formaldehyde processing and provided a chamber-experimen...

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Veröffentlicht in:Proceedings of the National Academy of Sciences - PNAS 2023-11, Vol.120 (48), p.e2304650120-e2304650120
Hauptverfasser: Nguyen, Thanh Lam, Peeters, Jozef, Müller, Jean-François, Perera, Ajith, Bross, David H, Ruscic, Branko, Stanton, John F
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Sprache:eng
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Zusammenfassung:Atmospheric formic acid is severely underpredicted by models. A recent study proposed that this discrepancy can be resolved by abundant formic acid production from the reaction (1) between hydroxyl radical and methanediol derived from in-cloud formaldehyde processing and provided a chamber-experiment-derived rate constant, = 7.5 × 10 cm s . High-level accuracy coupled cluster calculations in combination with -resolved two-dimensional master equation analyses yield = (2.4 ± 0.5) × 10 cm s for relevant atmospheric conditions ( = 260-310 K and = 0-1 atm). We attribute this significant discrepancy to HCOOH formation from other molecules in the chamber experiments. More importantly, we show that reversible aqueous processes result indirectly in the equilibration on a 10 min. time scale of the gas-phase reaction [Formula: see text] (2) with a HOCH OH to HCHO ratio of only . 2%. Although HOCH OH outgassing upon cloud evaporation typically increases this ratio by a factor of 1.5-5, as determined by numerical simulations, its in-cloud reprocessing is shown using a global model to strongly limit the gas-phase sink and the resulting production of formic acid. Based on the combined findings in this work, we derive a range of 1.2-8.5 Tg/y for the global HCOOH production from cloud-derived HOCH OH reacting with OH. The best estimate, 3.3 Tg/y, is about 30 times less than recently reported. The theoretical equilibrium constant (2) determined in this work also allows us to estimate the Henry's law constant of methanediol (8.1 × 10 M atm at 280 K).
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.2304650120