Geochemical and Photochemical Constraints on S[IV] Concentrations in Natural Waters on Prebiotic Earth
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AGU Advances - 2023 - Ranjan - ...
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Ranjan, SukritAbdelazim, Khaled
Lozano, Gabriella G.
Mandal, Sangita
Zhou, Cindy Y.
Kufner, Corinna L.
Todd, Zoe R.
Sahai, Nita
Sasselov, Dimitar D.
Affiliation
Lunar & Planetary Laboratory/Department of Planetary ScienceIssue Date
2023-12-15Keywords
General Earth and Planetary SciencesEarly Earth
Prebiotic environment
Modeling studies
Prebiotic chemistry
Sulfite
Sulfur
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American Geophysical Union (AGU)Citation
Ranjan, S., Abdelazim, K., Lozano, G. G., Mandal, S., Zhou, C. Y., Kufner, C. L., et al. (2023). Geochemical and photochemical constraints on S[IV] concentrations in natural waters on prebiotic Earth. AGU Advances, 4, e2023AV000926. https://doi. org/10.1029/2023AV000926Journal
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© 2023. The Authors. This is an open access article under the terms of the Creative Commons Attribution-NonCommercial License.Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
Aqueous S[IV] species (HSO3-, SO3[2-]) derived from volcanogenic atmospheric SO2 are important to planetary habitability through their roles in proposed origins-of-life chemistry and influence on atmospheric sulfur haze formation, but the early cycling of S[IV] is poorly understood. Here, we combine new laboratory constraints on S[IV] disproportionation kinetics with a novel aqueous photochemistry model to estimate the concentrations of S[IV] in natural waters on prebiotic Earth. We show that S[IV] disproportionation is slow in pH ≥ 7 waters, with timescale T ≥ 1 year at room temperature, meaning that S[IV] was present in prebiotic natural waters. However, we also show that photolysis of S[IV] by UV light on prebiotic Earth limited [S[IV]] < 100 µM in global-mean steady-state. Because of photolysis, [S[IV]] was much lower in natural waters compared to the concentrations generally invoked in laboratory simulations of origins-of-life chemistry (≥10 mM), meaning further work is needed to confirm whether laboratory S[IV]-dependent prebiotic chemistries could have functioned in nature. [S[IV]] ≥ 1 µM in terrestrial waters for: (a) SO2 outgassing ≥20× modern, (b) pond depths <10 cm, or (c) UV-attenuating agents present in early waters or the prebiotic atmosphere. Marine S[IV] was sub-saturated with respect to atmospheric SO2, meaning that atmospheric SO2 deposition was efficient and that, within the constraints of present knowledge, UV-attenuating sulfur hazes could only have persisted on prebiotic Earth if sulfur emission rates were very high (≳100× modern). Our work illustrates the synergy between planetary science, geochemistry and synthetic organic chemistry toward understanding the emergence and maintenance of life on early Earth.Note
Open access journalISSN
2576-604XEISSN
2576-604XVersion
Final published versionSponsors
Simons Foundation. Grant Numbers: 495062, 390360 National Aeronautics and Space Administration. Grant Numbers: HST:HF2-51471, NAS5-26555, 80NSSC18K1139, RK558-G2 National Science Foundation. Grant Number: EAR 1829695ae974a485f413a2113503eed53cd6c53
10.1029/2023av000926
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Except where otherwise noted, this item's license is described as © 2023. The Authors. This is an open access article under the terms of the Creative Commons Attribution-NonCommercial License.