Distinct types of C-H-O-N atmospheres and surface pressures depending on melt redox state and outgassing efficiency

IF 2.5 2区物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS

Icarus Pub Date : 2025-01-03 DOI:10.1016/j.icarus.2024.116450

Caroline Brachmann , Lena Noack , Philipp Alexander Baumeister , Frank Sohl

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Abstract

After the magma ocean state, secondary atmospheres build up via early volcanic degassing of planetary interiors. The terrestrial planets Venus, Earth, and Mars are believed to have originated from similar source material but reveal distinct present-day atmospheric compositions, pressures, and temperatures. To investigate how such diverse atmospheres emerge, we have built a three-step model coupling mantle and atmospheric composition. The model incorporates mantle melting, melt ascent, and volcanic degassing. Additionally, it includes atmospheric equilibrium chemistry, taking into account processes such as water condensation and hydrogen escape. Key parameters such as mantle oxygen fugacity, melt production rates, surface temperature, and volatile abundance in the mantle, were varied to understand their impact on atmospheric composition and pressure. For reduced mantles with redox states below IW +1, atmospheric pressures remain strongly limited to a maximum of 2 bar due to the outgassing of predominantly light species that are prone to atmospheric escape or condensation. Above IW +1, atmospheric pressure can reach several tens of bars depending on the outgassing efficiency. For high-pressure atmospheres, CO₂ is the main atmospheric species observed in our models. For oxidized low-pressure atmospheres, depending on temperature, atmospheres can be either water-rich or also CO₂-dominated. For reducing atmospheres, nitrogen species tend to dominate the atmospheres, with NH₃ for colder atmospheres and N₂ for warmer atmospheres. CH₄ becomes dominant only in a narrow parameter space at redox states around IW +0.5 to IW +2 and is favored by lower atmospheric temperatures.

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不同类型的C-H-O-N气氛和表面压力取决于熔体氧化还原状态和放气效率

在岩浆海洋状态之后，通过早期火山对行星内部的脱气形成了次级大气。类地行星金星、地球和火星被认为起源于相似的物质来源，但显示出不同的大气成分、压力和温度。为了研究这种不同的大气是如何出现的，我们建立了一个耦合地幔和大气成分的三步模型。该模型包括地幔融化、熔体上升和火山脱气。此外，它还包括大气平衡化学，考虑到水凝结和氢逸出等过程。通过改变地幔氧逸度、熔体生成速率、表面温度和地幔挥发物丰度等关键参数，了解它们对大气成分和压力的影响。对于氧化还原状态低于IW +1的还原地幔，大气压力仍然强烈限制在最大2bar，这是由于主要轻物质的排气，这些物质容易从大气中逃逸或凝结。在IW +1以上，根据放气效率的不同，大气压力可达几十巴。对于高压大气，在我们的模式中观测到的主要大气物质是二氧化碳。对于氧化的低压大气，根据温度的不同，大气可能富含水，也可能以二氧化碳为主。在还原性大气中，氮气种类往往占主导地位，NH3用于较冷的大气，N2用于较热的大气。CH4仅在IW +0.5至IW +2氧化还原态的狭窄参数空间中占主导地位，且受较低大气温度的影响。

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

Icarus 地学天文-天文与天体物理

CiteScore

6.30

自引率

18.80%

发文量

356

审稿时长

2-4 weeks

期刊介绍： Icarus is devoted to the publication of original contributions in the field of Solar System studies. Manuscripts reporting the results of new research - observational, experimental, or theoretical - concerning the astronomy, geology, meteorology, physics, chemistry, biology, and other scientific aspects of our Solar System or extrasolar systems are welcome. The journal generally does not publish papers devoted exclusively to the Sun, the Earth, celestial mechanics, meteoritics, or astrophysics. Icarus does not publish papers that provide "improved" versions of Bode''s law, or other numerical relations, without a sound physical basis. Icarus does not publish meeting announcements or general notices. Reviews, historical papers, and manuscripts describing spacecraft instrumentation may be considered, but only with prior approval of the editor. An entire issue of the journal is occasionally devoted to a single subject, usually arising from a conference on the same topic. The language of publication is English. American or British usage is accepted, but not a mixture of these.