可居住性:从恒星到细胞

IF 27.8 1区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS The Astronomy and Astrophysics Review Pub Date : 2010-06-08 DOI:10.1007/s00159-010-0030-4
Emmanuelle J. Javaux, Véronique Dehant
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引用次数: 25

摘要

为了确定在太阳系或其他太阳系外的什么地方寻找生命,基于我们唯一的生物行星样本——地球,人们提出了宜居性的概念。可居住性可以定义为活跃生命存在的必要条件,即使它不存在。在天文学中,宜居带(HZ)是指太阳或恒星周围的区域,在那里温度条件允许液态水存在于其表面。这种可居住性概念可以从不同的科学角度和不同的空间和时间尺度来考虑。在这些不同尺度上描述宜居性需要跨学科的研究。在这篇文章中,我们选择发展地球物理、地质和生物方面,并坚持需要将它们整合起来,特别关注我们邻近的行星,火星和金星。重要的地球动力学过程可能影响行星的可居住条件。动力学过程,如内部发电机、磁场、大气、板块构造、地幔对流、火山活动、热构造演化、陨石撞击和侵蚀,改变了行星表面、存在液态水的可能性、热状态、能量收支和营养物质的可用性。因此,它们在行星上生命的持续存在中发挥了作用。在4.4和4.0之间的冥古宙,地球有液态水海洋和一些大陆地壳?Ga (Ga:数十亿年前),可能很早就适合居住。生命的起源尚不清楚;但已知的最古老的生命痕迹是太古宙早期(~3.5亿古)。对岩石记录中记录的早期地球栖息地的研究提供了适合地球以外生命的可能栖息地的信息。今天生命茁壮成长的环境条件的极端值也可以用来描述生命存在的“包络线”和潜在的地外栖息地的范围。生命对营养物质的需求用于细胞成分的生物合成以及生长、繁殖、运输和运动,这可能表明,一个动态的岩石行星需要有热液活动和地形的形成、液态水的改变、侵蚀和径流,以补充营养物质和维持生命(正如我们所知)。宜居性的概念是非常以地球为中心的,因为我们只有一个生物星球可以研究。然而,其他地方的生命很可能以有机化学为基础,并通过微观或宏观地改变其环境的物理化学特征,留下过去或最近存在和新陈代谢的痕迹。这些变化发生的程度将决定我们在天体生物学探索中发现它们的能力。研究生命进化的主要步骤可能有助于确定探测到地球以外生命(如我们所知)的可能性,以及探测其痕迹所需的技术,无论是形态的、化学的、同位素的还是光谱的。
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Habitability: from stars to cells

To determine where to search for life in our solar system or in other extrasolar systems, the concept of habitability has been developed, based on the only sample we have of a biological planet—the Earth. Habitability can be defined as the set of the necessary conditions for an active life to exist, even if it does not exist. In astronomy, a habitable zone (HZ) is the zone defined around a sun/star, where the temperature conditions allow liquid water to exist on its surface. This habitability concept can be considered from different scientific perspectives and on different spatial and time scales. Characterizing habitability at these various scales requires interdisciplinary research. In this article, we have chosen to develop the geophysical, geological, and biological aspects and to insist on the need to integrate them, with a particular focus on our neighboring planets, Mars and Venus. Important geodynamic processes may affect the habitability conditions of a planet. The dynamic processes, e.g., internal dynamo, magnetic field, atmosphere, plate tectonics, mantle convection, volcanism, thermo-tectonic evolution, meteorite impacts, and erosion, modify the planetary surface, the possibility to have liquid water, the thermal state, the energy budget, and the availability of nutrients. They thus play a role in the persistence of life on a planet. Earth had a liquid water ocean and some continental crust in the Hadean between 4.4 and 4.0?Ga (Ga: billions years ago), and may have been habitable very early on. The origin of life is not understood yet; but the oldest putative traces of life are early Archean (~3.5?Ga). Studies of early Earth habitats documented in the rock record hosting fossil life traces provide information about possible habitats suitable for life beyond Earth. The extreme values of environmental conditions in which life thrives today can also be used to characterize the “envelope” of the existence of life and the range of potential extraterrestrial habitats. The requirement of nutrients by life for biosynthesis of cellular constituents and for growth, reproduction, transport, and motility may suggest that a dynamic and rocky planet with hydrothermal activity and formation of relief, liquid water alteration, erosion, and runoff is required to replenish nutrients and to sustain life (as we know it). The concept of habitability is very Earth-centric, as we have only one biological planet to study. However, life elsewhere would most probably be based on organic chemistry and leave traces of its past or recent presence and metabolism by modifying microscopically or macroscopically the physico-chemical characteristics of its environment. The extent to which these modifications occur will determine our ability to detect them in astrobiological exploration. Looking at major steps in the evolution of life may help determining the probability of detecting life (as we know it) beyond Earth and the technology needed to detect its traces, be they morphological, chemical, isotopic, or spectral.

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来源期刊
The Astronomy and Astrophysics Review
The Astronomy and Astrophysics Review 地学天文-天文与天体物理
CiteScore
45.00
自引率
0.80%
发文量
7
期刊介绍: The Astronomy and Astrophysics Review is a journal that covers all areas of astronomy and astrophysics. It includes subjects related to other fields such as laboratory or particle physics, cosmic ray physics, studies in the solar system, astrobiology, instrumentation, and computational and statistical methods with specific astronomical applications. The frequency of review articles depends on the level of activity in different areas. The journal focuses on publishing review articles that are scientifically rigorous and easily comprehensible. These articles serve as a valuable resource for scientists, students, researchers, and lecturers who want to explore new or unfamiliar fields. The journal is abstracted and indexed in various databases including the Astrophysics Data System (ADS), BFI List, CNKI, CNPIEC, Current Contents/Physical, Chemical and Earth Sciences, Dimensions, EBSCO Academic Search, EI Compendex, Japanese Science and Technology, and more.
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