Eta-Earth Revisited II: Deriving a Maximum Number of Earth-Like Habitats in the Galactic Disk.

IF 3.5 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Astrobiology Pub Date : 2024-10-01 DOI:10.1089/ast.2023.0076
Manuel Scherf, Helmut Lammer, Laurenz Spross
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Abstract

In Lammer et al. (2024), we defined Earth-like habitats (EHs) as rocky exoplanets within the habitable zone of complex life (HZCL) on which Earth-like N2-O2-dominated atmospheres with minor amounts of CO2 can exist, and derived a formulation for estimating the maximum number of EHs in the galaxy given realistic probabilistic requirements that have to be met for an EH to evolve. In this study, we apply this formulation to the galactic disk by considering only requirements that are already scientifically quantifiable. By implementing literature models for star formation rate, initial mass function, and the mass distribution of the Milky Way, we calculate the spatial distribution of disk stars as functions of stellar mass and birth age. For the stellar part of our formulation, we apply existing models for the galactic habitable zone and evaluate the thermal stability of nitrogen-dominated atmospheres with different CO2 mixing ratios inside the HZCL by implementing the newest stellar evolution and upper atmosphere models. For the planetary part, we include the frequency of rocky exoplanets, the availability of surface water and subaerial land, and the potential requirement of hosting a large moon by evaluating their importance and implementing these criteria from minima to maxima values as found in the scientific literature. We also discuss further factors that are not yet scientifically quantifiable but may be requirements for EHs to evolve. Based on such an approach, we find that EHs are relatively rare by obtaining plausible maximum numbers of 2.5-2.4+71.6×105 and 0.6-0.59+27.1×105planets that can potentially host N2-O2-dominated atmospheres with maximum CO2 mixing ratios of 10% and 1%, respectively, implying that, on average, a minimum of 103-106rocky exoplanets in the HZCL are needed for 1 EH to evolve. The actual number of EHs, however, may be substantially lower than our maximum ranges since several requirements with unknown occurrence rates are not included in our model (e.g., the origin of life, working carbon-silicate and nitrogen cycles); this also implies extraterrestrial intelligence (ETI) to be significantly rarer still. Our results illustrate that not every star can host EHs nor can each rocky exoplanet within the HZCL evolve such that it might be able to host complex animal-like life or even ETIs. The Copernican Principle of Mediocrity therefore cannot be applied to infer that such life will be common in the galaxy.

Eta-Earth Revisited II: Deriving a Maximum Number of Earth-Like Habitats in the Galactic Disk.
在 Lammer 等人(2024 年)的研究中,我们将类地栖息地(EHs)定义为复合生命宜居带(HZCL)内的岩石系外行星,在这些行星上可以存在以 N2-O2 为主、含有少量 CO2 的类地大气,并推导出了一种公式,用于在 EH 演化必须满足的现实概率要求下估计银河系中 EHs 的最大数量。在本研究中,我们将这一公式应用于星系盘,只考虑已经可以科学量化的要求。通过实施关于恒星形成率、初始质量函数和银河质量分布的文献模型,我们计算了作为恒星质量和诞生年龄函数的星盘恒星空间分布。在恒星部分,我们应用了现有的银河宜居带模型,并通过实施最新的恒星演化和高层大气模型,评估了HZCL内部不同二氧化碳混合比的氮主导大气的热稳定性。在行星部分,我们评估了岩石系外行星的频率、地表水和地下陆地的可用性,以及容纳一颗大卫星的潜在要求,并将这些标准从科学文献中发现的最小值到最大值进行了评估。我们还讨论了更多尚未科学量化但可能是 EHs 演化要求的因素。基于这种方法,我们发现EHs是相对罕见的,因为我们得到了2.5-2.4+71.6×105颗行星和0.6-0.59+27.1×105颗行星的合理最大数量,这些行星有可能承载N2-O2为主的大气,最大二氧化碳混合比分别为10%和1%,这意味着平均来说,HZCL中至少需要103-106颗系外行星才能演化出1颗EH。然而,EHs的实际数量可能远远低于我们的最大范围,因为我们的模型中没有包括一些发生率未知的要求(例如生命起源、碳硅酸盐和氮循环的工作);这也意味着地外智慧(ETI)更加罕见。我们的研究结果表明,并非每颗恒星都能孕育 EHs,HZCL 中的每颗岩质系外行星也不可能进化到能够孕育复杂的类动物生命甚至 ETIs 的程度。因此,哥白尼中庸原则并不能用来推断这种生命会在银河系中普遍存在。
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
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
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