Oxygen Bounty for Earth-like exoplanets: Spectra of Earth through the Phanerozoic

Q1 Earth and Planetary Sciences Monthly Notices of the Royal Astronomical Society: Letters Pub Date : 2023-10-13 DOI:10.1093/mnrasl/slad147

R C Payne, L Kaltenegger

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Abstract

Abstract In the search for life in the universe, Earth provides a template of evolution for the one habitable planet we know. Earth's atmospheric composition has changed significantly throughout its history. The last 500 million years -the Phanerozoic Eon, which includes the origins of animals, dinosaurs, and land plants- saw oxygen rise from ≤10% to 35%. But the resulting transmission spectra are a crucial missing piece in our search for signs of life in exoplanet atmospheres. Here, we simulate the atmosphere and transmission spectra of the Phanerozoic, using estimates from established climate models, and present the first high-resolution transmission spectra for Phanerozoic Earth. We demonstrate that the spectral biosignature pairs O2+CH4 and O3+CH4 in the atmosphere of a transiting Earth-like planet would indicate a biosphere, with O2 and O3 features potentially stronger than for modern Earth. The full model and high-resolution transmission spectra, covering 0.4–20 μm, are available online and provides a tool to plan and optimize observations, train retrieval methods, and interpret upcoming observations with ground- and space-based telescopes.

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类地系外行星的富氧:地球到显生宙的光谱

在寻找宇宙生命的过程中，地球为我们所知的一颗宜居行星的进化提供了一个模板。地球的大气成分在其整个历史中发生了重大变化。在过去的5亿年——显生宙，包括动物、恐龙和陆生植物的起源——氧气从不超过10%上升到35%。但由此产生的透射光谱是我们寻找系外行星大气中生命迹象的关键缺失部分。在这里，我们模拟显生宙的大气和透射光谱，利用已建立的气候模式的估计，并提出了显生宙地球的第一个高分辨率透射光谱。我们证明，在一颗凌日类地行星的大气中，光谱生物特征对O2+CH4和O3+CH4将表明一个生物圈，O2和O3的特征可能比现代地球更强。完整的模型和高分辨率透射光谱覆盖0.4-20 μm，可在线获取，为规划和优化观测、训练检索方法以及解释地面和天基望远镜即将进行的观测提供了工具。

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来源期刊

Monthly Notices of the Royal Astronomical Society: Letters Earth and Planetary Sciences-Space and Planetary Science

CiteScore

8.80

自引率

0.00%

发文量

136

期刊介绍： For papers that merit urgent publication, MNRAS Letters, the online section of Monthly Notices of the Royal Astronomical Society, publishes short, topical and significant research in all fields of astronomy. Letters should be self-contained and describe the results of an original study whose rapid publication might be expected to have a significant influence on the subsequent development of research in the associated subject area. The 5-page limit must be respected. Authors are required to state their reasons for seeking publication in the form of a Letter when submitting their manuscript.

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