Self-Oxidation of the Atmospheres of Rocky Planets with Implications for the Origin of Life.

IF 3.5 3区物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS

Astrobiology Pub Date : 2024-09-01 DOI:10.1089/ast.2023.0104

Anders Johansen, Eloi Camprubi, Elishevah van Kooten, H Jens Hoeijmakers

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Abstract

Rocky planets may acquire a primordial atmosphere by the outgassing of volatiles from their magma ocean. The distribution of O between H₂O, CO, and CO₂ in chemical equilibrium subsequently changes significantly with decreasing temperature. We consider here two chemical models: one where CH₄ and NH₃ are assumed to be irrevocably destroyed by photolysis and second where these molecules persist. In the first case, we show that CO cannot coexist with H₂O, since CO oxidizes at low temperatures to form CO₂ and H₂. In both cases, H escapes from the thermosphere within a few 10 million years by absorption of stellar XUV radiation. This escape drives an atmospheric self-oxidation process, whereby rocky planet atmospheres become dominated by CO₂ and H₂O regardless of their initial oxidation state at outgassing. HCN is considered a potential precursor of prebiotic compounds and RNA. Oxidizing atmospheres are inefficient at producing HCN by lightning. Alternatively, we have demonstrated that lightning-produced NO, which dissolves as nitrate in oceans, and interplanetary dust particles may be the main sources of fixed nitrogen in emerging biospheres. Our results highlight the need for origin-of-life scenarios where the first metabolism fixes its C from CO₂, rather than from HCN and CO.

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岩石行星大气的自氧化作用对生命起源的影响

岩石行星可能是通过岩浆海洋中挥发物的排出而获得原始大气的。在化学平衡状态下，O 在 H2O、CO 和 CO2 之间的分布会随着温度的降低而发生显著变化。我们在此考虑了两种化学模型：一种是假定 CH4 和 NH3 被光解不可逆转地摧毁，另一种是假定这些分子持续存在。在第一种情况下，我们发现 CO 无法与 H2O 共存，因为 CO 在低温下会氧化生成 CO2 和 H2。在这两种情况下，H 都会在几千万年内通过吸收恒星的 XUV 辐射从热层中逃逸出来。这种逸出推动了大气中的自氧化过程，据此，岩质行星大气变得以 CO2 和 H2O 为主，而不管它们在排气时的初始氧化状态如何。HCN 被认为是前生物化合物和 RNA 的潜在前体。氧化大气通过闪电产生 HCN 的效率很低。另外，我们已经证明，闪电产生的 NO（在海洋中溶解为硝酸盐）和行星际尘埃粒子可能是新兴生物圈中固定氮的主要来源。我们的研究结果凸显了生命起源情景的必要性，在这种情景中，第一次新陈代谢从 CO2 而不是 HCN 和 CO 中固定其 C。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Astrobiology 生物-地球科学综合

CiteScore

7.70

自引率

11.90%

发文量

100

审稿时长

3 months

期刊介绍： Astrobiology is the most-cited peer-reviewed journal dedicated to the understanding of life''s origin, evolution, and distribution in the universe, with a focus on new findings and discoveries from interplanetary exploration and laboratory research. Astrobiology coverage includes: Astrophysics; Astropaleontology; Astroplanets; Bioastronomy; Cosmochemistry; Ecogenomics; Exobiology; Extremophiles; Geomicrobiology; Gravitational biology; Life detection technology; Meteoritics; Planetary geoscience; Planetary protection; Prebiotic chemistry; Space exploration technology; Terraforming