Sukrit Ranjan, Khaled Abdelazim, Gabriella G. Lozano, Sangita Mandal, Cindy Y. Zhou, Corinna L. Kufner, Zoe R. Todd, Nita Sahai, Dimitar D. Sasselov
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Sasselov","doi":"10.1029/2023AV000926","DOIUrl":null,"url":null,"abstract":"<p>Aqueous S[IV] species (<math>\n <semantics>\n <mrow>\n <msubsup>\n <mrow>\n <mi>H</mi>\n <mi>S</mi>\n <mi>O</mi>\n </mrow>\n <mn>3</mn>\n <mo>−</mo>\n </msubsup>\n </mrow>\n <annotation> ${\\mathrm{H}\\mathrm{S}\\mathrm{O}}_{3}^{-}$</annotation>\n </semantics></math>, <math>\n <semantics>\n <mrow>\n <msubsup>\n <mrow>\n <mi>S</mi>\n <mi>O</mi>\n </mrow>\n <mn>3</mn>\n <mrow>\n <mn>2</mn>\n <mo>−</mo>\n </mrow>\n </msubsup>\n </mrow>\n <annotation> ${\\mathrm{S}\\mathrm{O}}_{3}^{2-}$</annotation>\n </semantics></math>) derived from volcanogenic atmospheric SO<sub>2</sub> 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 <i>T</i> ≥ 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) SO<sub>2</sub> 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 SO<sub>2</sub>, meaning that atmospheric SO<sub>2</sub> 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). 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引用次数: 0
摘要
水溶液S[IV]组分(H S O 3−${\ mathm {H}\ mathm {S}\ mathm {O}}_{3}^{-}$,从火山成因大气中产生的SO2的SO 3 2−${\mathrm{S}\mathrm{O}}_{3}^{2-}$)对行星的可居住性至关重要提出了生命起源化学及其对大气硫霾形成的影响,但对S[IV]的早期循环知之甚少。在这里,我们结合了新的实验室对S[IV]歧化动力学的约束和一种新的水光化学模型来估计生命前地球自然水体中S[IV]的浓度。结果表明,S[IV]在pH≥7的水体中歧化缓慢,在室温下时间标度T≥1年,这意味着S[IV]存在于益生元天然水体中。然而,我们也表明,在益生元地球上,紫外光对S[IV]的光解作用有限[S[IV]] <100µM在全局平均稳态。由于光解作用,与生命起源化学的实验室模拟(≥10 mM)中通常使用的浓度相比,天然水体中的[S[IV]]浓度要低得多,这意味着需要进一步的工作来确认实验室中依赖于S[IV]的益生元化学物质是否可能在自然界中发挥作用。[S[IV]]在陆地水域≥1 μ M的条件下:(a) SO2放气≥20倍现代,(b)池塘深度≥10厘米,或(c)早期水域或益生元大气中存在的紫外线衰减剂。海洋S[IV]相对于大气SO2是亚饱和的,这意味着大气SO2沉积是有效的,并且,在现有知识的限制下,只有当硫排放率非常高(> 100倍现代)时,紫外线衰减的硫雾才可能在益生元地球上持续存在。我们的工作说明了行星科学,地球化学和合成有机化学之间的协同作用,以了解早期地球上生命的出现和维持。
Geochemical and Photochemical Constraints on S[IV] Concentrations in Natural Waters on Prebiotic Earth
Aqueous S[IV] species (, ) 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.
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