Origins and Early Evolution of the Atmosphere and the Oceans

IF 6.8 3区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Geochemical Perspectives Pub Date : 2020-10-01 DOI:10.7185/geochempersp.9.2
B. Marty
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引用次数: 7

Abstract

My journey in science began with the study of volcanic gases, sparking an interest in the origin, and ultimate fate, of the volatile elements in the interior of our planet. How did these elements, so crucial to life and our surface environment, come to be sequestered within the deepest regions of the Earth, and what can they tell us about the processes occurring there? My approach has been to establish geochemical links between the noble gases, physical tracers par excellence, with major volatile elements of environmental importance, such as water, carbon and nitrogen, in mantle-derived rocks and gases. From these analyses we have learned that the Earth is relatively depleted in volatile elements when compared to its potential cosmochemical ancestors (e.g., ~2 ppm nitrogen compared to several hundreds of ppm in primitive meteorites) and that natural fluxes of carbon are two orders of magnitude lower than those emitted by current anthropogenic activity. Further insights into the origin of terrestrial volatiles have come from space missions that documented the composition of the proto-solar nebula and the outer solar system. The consensus behind the origin of the atmosphere and the oceans is evolving constantly, although recently a general picture has started to emerge. At the dawn of the solar system, the volatile-forming elements (H, C, N, noble gases) that form the majority of our atmosphere and oceans were trapped in solid dusty phases (mostly in ice beyond the snowline and organics everywhere). These phases condensed from the proto-solar nebula gas, and/or were inherited from the interstellar medium. These accreted together within the next few million years to form the first planetesimals, some of which underwent differentiation very early on. The isotopic signatures of volatiles were also fixed very early and may even have preceded the first episodes of condensation and accretion. Throughout the accretion of the Earth, volatile elements were delivered by material from both the inner (dry, volatile-poor) and outer (volatile-rich) solar system. This delivery was concomitant with the metals and silicates that form the bulk of the planet. The contribution of bodies that formed in the far outer solar system, a region now populated by comets, is likely to have been very limited. In that sense, volatile elements were contributed continuously throughout Earth’s accretion from inner solar system reservoirs, which also provided the silicates and metal building blocks of the inner planets. Following accretion, it likely took a few hundred million years for the Earth’s atmosphere and oceans to stabilise. Luckily, we have been able to access a compositional record of the early atmosphere and oceans through the analysis of palaeo-atmospheric fluids trapped in Archean hydrothermal quartz. From these analyses, it appears that the surface reservoirs of the Earth evolved due to interactions between the early Sun and the top of the atmosphere, as well as the development of an early biosphere that progressively altered its chemistry.
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大气和海洋的起源和早期演变
我的科学之旅始于对火山气体的研究,激发了人们对地球内部挥发性元素的起源和最终命运的兴趣。这些对生命和地表环境至关重要的元素是如何被隔离在地球最深处的,它们能告诉我们那里发生的过程吗?我的方法是在稀有气体(卓越的物理示踪剂)与地幔衍生岩石和气体中具有重要环境意义的主要挥发性元素(如水、碳和氮)之间建立地球化学联系。从这些分析中,我们了解到,与潜在的宇宙化学祖先相比,地球的挥发性元素相对较少(例如,约2ppm的氮,而原始陨石中的氮含量为数百ppm),碳的自然通量比当前人类活动排放的碳通量低两个数量级。太空任务记录了原太阳星云和外太阳系的组成,进一步深入了解了地球挥发物的起源。关于大气层和海洋起源的共识正在不断演变,尽管最近开始出现一个总体情况。在太阳系诞生之初,构成我们大气层和海洋大部分的挥发性形成元素(H、C、N、稀有气体)被困在固体尘埃相中(主要存在于雪线外的冰和各处的有机物中)。这些相是从原太阳星云气体中凝结而来的,和/或是从星际介质中继承而来的。在接下来的几百万年里,这些星子聚集在一起,形成了第一批星子,其中一些星子很早就经历了分化。挥发物的同位素特征也很早就固定下来,甚至可能早在第一次凝结和吸积之前。在地球吸积的整个过程中,挥发性元素是由内部(干燥、挥发性差)和外部(挥发性丰富)太阳系的物质输送的。这种输送伴随着形成地球大部分的金属和硅酸盐。在遥远的外太阳系形成的天体的贡献可能非常有限,该地区现在有彗星居住。从这个意义上说,在整个地球吸积过程中,挥发性元素不断地从太阳系内部的储层中产生,这些储层也提供了内行星的硅酸盐和金属构件。在吸积之后,地球的大气层和海洋可能需要数亿年才能稳定下来。幸运的是,我们能够通过分析太古代热液石英中捕获的古大气流体,获得早期大气和海洋的成分记录。从这些分析来看,地球表面的储层似乎是由于早期太阳和大气层顶部之间的相互作用以及早期生物圈的发展而进化的,该生物圈逐渐改变了其化学性质。
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来源期刊
Geochemical Perspectives
Geochemical Perspectives GEOCHEMISTRY & GEOPHYSICS-
CiteScore
0.80
自引率
0.00%
发文量
1
期刊介绍: Each issue of Geochemical Perspectives presents a single article with an in-depth view on the past, present and future of a field of geochemistry, seen through the eyes of a highly respected member of our community. The articles combine science and history of the field’s development and the scientist’s opinions about future directions. We expect personal glimpses into the author’s scientific life, how ideas were generated, pitfalls and triumphs along the way, and how ideas were adopted to carry our field further. Perspectives articles are intended for the entire geochemical community, not for experts. They are not reviews or monographs or text books. They go beyond the current state of the art, providing opinions about future directions and impact in the field.
期刊最新文献
Carbon Capture and Storage: From Global Cycles to Global Solutions A journey in Noble Gas Cosmochemistry and Geochemistry Anoxia-Related Biogeochemistry of North Indian Ocean Academic Reminiscences and Thermodynamics-Kinetics of Thermo-Barometry-Chronology Origins and Early Evolution of the Atmosphere and the Oceans
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