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1.
天体化学:地球起源与演化的几个关键问题 总被引:6,自引:1,他引:6
以近几年天体化学研究取得的一些重要成果,论述了对于认识地球的起源和演化进程的重要意义。地球主要由一套具有独立化学成分组成的硅酸盐质星子群随机碰撞吸积而成。地球的星子堆积形成方式和初始化学成分的不均一性制约着地球后期的非均一、非均变演化过程。以1800Ma为转折点,地球的演化具明显的两阶段演化特征:早期以初生壳体———星子源地体的形成和发展为特点,后期以岩石圈板块运动为特点。地球演化史中的地外撞击事件,是太阳系形成机制———碰撞吸积作用的继续,是地质历史生物、沉积、岩浆、构造等演化的重要营力之一。 相似文献
2.
以近几年天体化学研究取得的一些重要成果,论述了对于认识地球的起源和演化进程的重要意义。地球主要由一套具有独立化学成分组成的硅酸盐质星子群随机碰撞吸积而成。地球的星子堆积形成方式和初始化学成分的不均一性制约着地球后期的非均一,非均变演化过程。以1800Ma为转折点,地球的演化具明显的两阶段演化特征:早期以初生壳体-星子源地体的形成和发展为特点,后期以岩石圈板块运动为特点。 相似文献
3.
超大型矿床密集区的成因及预测 总被引:1,自引:0,他引:1
首次提出地球上矿产资源分布的不均匀主要与太阳系的起源有关。水星、金星、地球、火星、小行星的幔,主要分别由E群、H群、L群、LL群和C群陨石物质组成的星子聚合而成、由此造成行星幔横向不均匀性及幔表层矿产资源不均匀性的基础。由于不同元素在各类星子中分布的不均匀性程度不同,它们对超大型矿床密集区的控制也不一样。富含成矿元素的星子被吸积于上地幔表层,形成了原始矿源区。当地壳形成后,大陆岩石圈没有被软流层的对流作用均匀化,虽经几十亿年的地质作用改造,这一原始矿源区依然存在。通过分析不同群的球粒陨石组分等特征,并结合成矿时代、成矿带及成矿作用改造特征等,可以对超大型矿床密集区进行远景预测。 相似文献
4.
本文从太阳星云演变模式入手,着重介绍地球的非均一堆积起源模式.指出地球的化学成分具有原始的不均一性;这种不均一性起源于前地球阶段堆积星子的不均一性.地球的星子吸积过程具有明显的两阶段性,即原地球吸积阶段和晚期吸积阶段,而后期的吸积过程对上地幔及地壳的化学成分不均一性的影响尤为显著.最后指出地球化学不均一性对超大型矿床分布的制约. 相似文献
5.
类地行星挥发性元素普遍亏损很可能是由于太阳星云早期剧烈的太阳活动引起的。当气体、尘粒、挥发性元素和水被驱赶出内太阳系时,只有米级到公里级的物质保存下来并堆积成星子,最终吸积星子形成类地行星。我们认为类地行星的初始物质主要是已分异的星子和一些未分异的球粒陨石质星子或不同类型的陨石母体,最靠近太阳形成的星子具有最低的FeO/(FeO+MgO)值,水星是在靠近太阳的高度还原条件下吸积成分类似EH球粒陨石的星子形成的。地球的初始物质为分异的铁陨石及H群球粒陨石。随着距太阳距离增大及温度降低,陨石形成的部位大致为:EH、EL-IAB-SNC(辉玻无球粒陨石、辉橄无球粒陨石、纯橄无球粒陨石)-Euc(钙长辉长无球粒陨石)-H、L、LL-CV、CM、CO-Cl-彗星。物体之间、星子之间及行星与星子之间的碰撞对太阳系的形成和演化起着重要的作用。 相似文献
6.
在建立了小行星区星云凝聚模型的基础上,对类地行星区中上物质(硅酸盐、氧化物、金属、硫化物等)的凝聚作用,以及凝聚物的水化作用进行了讨论,进而建立了包括小行星区在内的整个类地行星区的星云凝聚模式。根据地球核慢质量比和关于地球初期演化的研究结果;使用顽火辉石球粒陨石和C1陨石的化学成分分别做为地球形成区中类顽火辉石球粒陨石质星子和类C1陨石质星子的成分数据;假定类顽火辉石无球粒陨石质星子的成分与类顽火辉石球粒陨石质星子的硅酸盐部分成分相同,计算出原始地球可能由1.58%的类铁陨石质星子、13.9%的类顽火辉石无球粒陨石质星子、82.52%类顽火辉石球粒陨石质星子、2%的类C1陨石质星子组成。 相似文献
7.
行星地球不均一成因和演化的理论框架初探 总被引:4,自引:0,他引:4
地球是太阳系的一部分 ,研究地球的成因和演化必须要与太阳系的形成结合起来。文章在综合最新的地球化学、地球物理和天体化学研究资料的基础上 ,对地球的不均一成因进行了理论上的推导。对星子学说、地球的多阶段堆积模型和地球化学不均一性以及它们的相互关系进行了论述 ,从行星演化的角度阐述地球不均一成因的理论框架。根据行星起源的星子学说 ,以及天体化学、地球化学和深部地质地球化学和地球物理资料的多重限制 ,行星地球的增生经历了两个主要阶段 ,即原地球的形成阶段和晚期星子堆积形成上地幔镶饰层阶段。早前寒武纪岩石的铅、钕、氧同位素的研究表明 ,在地球形成的初期就存在化学不均一性 ,而这种不均一性很可能代表初始堆积星子化学组成的差异 相似文献
8.
太阳星云凝集过程的岩石学模型:(Ⅲ)类地行星区星云凝集作用和地球… 总被引:2,自引:0,他引:2
在建立了小行星星云凝聚模型的基础上,对类地行星区中土物质(硅酸盐、氧化物、金属、硫化物等)的凝聚作用,以及凝聚物的水化作用进行了讨论。进而建立了包括小行星区在内的整个类地行星区的星云凝聚模式。根据地球核幔质量比和关于地球初期演化的研究结果:使用顽光辉石球粒陨石和C1陨石的化学成分分别做为地球形成区中类顽光辉石球粒陨石质星子和类C1陨石质星子和类C1陨石质星子的成分数据,假定类顽光辉石无球粒陨石质昨 相似文献
9.
地球环境演化的阶段性及其形成机制探讨 总被引:4,自引:0,他引:4
地球环境(大气圈、水圈)的演化具有明显的阶段性。撞击作用与地内核转变能是地球环境(大气圈、水圈)演化的根本机制。地球吸积形成期,原地球捕获太阳星云大气形成的原始大气经太阳风驱赶和星子撞击而逃逸,早期大规模的撞击过程又可能使地球上折矿物脱去挥发分,形成地球次生大气的一部分,也可使其次生大气部分脱离地球,地球形成期曾经历过撞击生气与气体逃逸的多次旋回,撞击作用决定其环境条件;地球形成之后,撞击作用仍起 相似文献
10.
陨石是来自含气体-尘粒的太阳早期星云盘凝聚和吸积的原始物质,大多数原始物质因吸积后的作用过程而改变(如月球、地球及火星样品),但有一些却完整的保存下来(如球粒陨石或球粒陨石中的难熔包体)。这些原始的物质通常依据同位素丰度特征来识别,依据其矿物-岩石学特征和成因可将已知的陨石划分许多更小的类型。陨石学及天体化学的新近进展包括:新近识别的陨石群;发现新类型球粒陨石及行星际尘粒中发现前太阳和星云组分;利用短寿命放射性核素完善了早期太阳系年代学;洞察宇宙化学丰度、分馏作用及星云源区及通过次生母体的作用过程阐释星云和前星云的记录。本文概述了早期太阳系内从星云到陨石的演化过程。依据这些资料,对早期太阳系所经历的多种核合成的输入、瞬时加热事件与星云动力学有一些新的认识,以及认识到小星子和行星体系的演化比以前预期的更快速。 相似文献
11.
本文评述了星云和星子假说、太阳星云的崩塌、星盘的形成和演化、颗粒生长、星子增生、类地行星和类木行星的形成、行星迁移,以及太阳和行星的演化。 相似文献
12.
A.G.W. Cameron 《Earth》1973,9(2):125-137
A brief introduction is given to the various approaches which have been followed in attempting to construct models of the origin of the solar system. The author then outlines in more detail one of the more recent approaches, involving models of a massive primitive solar nebula. In this approach a massive gaseous disk is first formed during the course of star formation, and the Sun must subsequently form from the disk as a result of hydrodynamical dissipation processes. Both the dissipation and the accompanying formation of the planets are estimated to require only a few thousand years. As a consequence, there was little time for the Earth to radiate its energy of gravitational accretion, and the primitive Earth must have been extremely hot. 相似文献
13.
S. Fred Singer 《Earth》1977,13(2):171-189
The study of the Earth—Moon system provides the connecting link between purely astronomical studies of the origin of the solar system and its planets, and geophysical and biological studies of the evolution of the Earth's geology, its surface features, atmosphere and hydrosphere, and of terrestrial life.A coherent account is presented here, based on the hypothesis that the Moon formed separately and was later captured by the Earth. The adoption of this hypothesis, together with the observed depletion of iron in the Moon, sets some important constraints on the development of condensation and agglomeration phenomena in the primeval solar nebula, which led to the formation of planetesimals, and ultimately to planets.Capture of the Moon also defines a severe heating event within the Earth, whereby its kinetic energy of rotation is largely dissipated internally by the mechanism of tidal friction. From this melting event dates the geologic, atmospheric, and oceanic history of the Earth. An attempt is made to account for the unique development of the Earth, especially in relation to Mars and Venus, its neighboring planets. 相似文献
14.
Michael J. Mottl Brian T. Glazer Ralf I. Kaiser Karen J. Meech 《Chemie der Erde / Geochemistry》2007,67(4):253-282
Water is formed from two of the three most abundant elements in the universe and so is abundant in interstellar space, in our Solar System, and on Earth, where it is an essential compound for the existence of life as we know it. Water ice acts as a substrate and reactant in interstellar clouds of gas and dust, enabling the formation of organic compounds that are important precursors to life and that eventually became incorporated into comets and asteroids in the early Solar System. Laboratory experiments have allowed us to infer the reaction pathways and mechanisms by which some of these compounds are formed. In these reactions, water can act as an energy transfer medium, increasing product yields, or it can lower yields by diluting reaction centers. Water can also destroy organic compounds when water ice decomposes under ionizing radiation and the decomposition products attack the compounds; whether this happens depends critically on temperature and structure of the ice, whether crystalline or amorphous. Ice structure and temperature also largely determine its gas content. As the solar nebula collapsed, icy mantles on interstellar grains probably sublimated and then recondensed onto other grains, thus influencing the transport of energy, mass, and angular momentum in the disk. Icy grains also influenced the temperature structure of the disk because they influence mean disk opacity. Outside the “snow line” at 3–5 AU icy grains accreted to become part of comets and planetesimals that occupy the region of the outer planets, the Kuiper belt, and the Oort cloud. Water was acquired by the growing Earth by several mechanisms. Evidence from noble gas isotopes indicates that Earth achieved sufficient mass fast enough to capture an early H-rich atmosphere from the Solar nebula itself. Although the remnant of this primary atmosphere is now found only in the mantle, it may also reside in the core, which could contain most of the H on Earth (or none at all). The bulk silicate Earth contains only 500–1100 ppm H2O, an amount small enough to explain by “wet” accretion, although most of it probably accumulated with the latter half of Earth's mass from wetter planetary embryos originating beyond 1.5 AU. Degassing on impact delivered water to Earth's surface, where it dissolved into a magma ocean, a process that likely saved it from loss during subsequent catastrophic impacts such as the Moon-forming giant impact, which resulted in >99% loss of the noble gas inventory. Although most of Earth's water probably came from meteoritic material, the depletion on Earth of Xe relative to Kr strongly suggests a role for comets. The role of water in supporting life is an essential one on Earth and probably elsewhere, given the unusual properties of water compared with other potentially abundant compounds. Its dipolarity, high boiling point and heat of vaporization and, for ice, melting temperature; its expansion on freezing; and its solvent properties make it an ideal medium for life. Life originated early on Earth, indicating an abundance of water, nutrients, precursor molecules, substrates, and appropriate physical and chemical conditions. Life adapted quickly to (and may have originated in) extreme environments, of heat, cold, dryness, saltiness, and acidity. This adaptation to extreme conditions bodes well for the prospect of finding life elsewhere in our Solar System and in planetary systems around other stars. 相似文献
15.
陨石氧同位素组成及其地学意义 总被引:1,自引:0,他引:1
介绍了各类陨石氧同位素组成的特点,对陨石氧同位素组成的主要成因观点进行了评述,结合地球的原始物质组成,讨论了陨石氧同位素组成的地球科学意义。 相似文献
16.
During the accretion of planets such as Earth, which are formed by collisional accretion of plan-etesimals, the probability
of capture of interplanetary bodies in planetocentric orbits is calculated following the approach of Hills (1973) and the
n-body simulation, using simplectic integration method. The simulation, taking an input mass equal to about 50% of the present
mass of the inner planets, distributed over a large number of planetoids, starting at 4 M y after the formation of solar system,
yielded four inner planets within a period of 30 M y. None of these seed bodies, out of which the planets formed, remained
at this time and almost 40% mass was transferred beyond 100 AU. Based on these calculations, we conclude that ∼ 1.4 times
the mass of the present inner planets was needed to accumulate them. The probability of capture of planetoids in geocentric
orbits is found to be negligible. The result emphasizes the computational difficulty in ’probability of capture’ of planetesimals
around the Earth before the giant impact. This conclusion, however, is in contradiction to the recent observations of asteroids
being frequently captured in transient orbits around the Earth, even when the current population of such interplanetary bodies
is smaller by several orders of magnitude compared to the planetary accumulation era. 相似文献
17.
《Chemie der Erde / Geochemistry》2021,81(3):125786
Stable potassium isotopes are one of the emerging non-traditional isotope systems enabled in recent years by the advance of Multi-Collector Inductively-Coupled-Plasma Mass-Spectrometry (MC-ICP-MS). In this review, we first summarize the geochemical and cosmochemical properties of K, its major reservoirs, and the analytical methods of K isotopes. Following this, we review recent literature on K isotope applications in the fields of geochemistry and cosmochemistry. Geochemically, K is a highly incompatible lithophile element, and a highly soluble, biophile element. The isotopic fractionation of K is relatively small during magmatic processes such as partial melting and fractional crystallization, whereas during low-temperature and biological processes fractionation is considerably larger. This resolvable fractionation has made K isotopes promising tracers for a variety of Earth and environmental processes, including chemical weathering, low-temperature alteration of igneous rocks, reverse weathering, and the recycling of sediments into the mantle during subduction. Sorption and interactions of aqueous K with different clay minerals during cation exchange and clay formation are likely to be of fundamental significance in generating much of the K isotope variability seen in samples from the Earth surface and samples carrying recycled surface materials from the deep Earth. The magnitude of this fractionation is process- and mineral-dependent. Comprehensive quantification of pertinent K isotope fractionation factors is currently lacking and urgently needed. Significant fractionation during biological activities, such as plant uptake, demonstrates the potential utility of K isotopes in the study of the nutrient cycle and its relation to the climate and various ecosystems, enabling new and largely unexplored avenues for future research.Of significant importance to the cosmochemistry community, K is a moderately volatile element with large variations in K/U ratio observed among chondrites and planetary materials. As this indicates different degrees of volatile depletion, it has become a fundamental chemical signature of both chondritic and planetary bodies. This volatile depletion has been attributed to various processes such as solar nebula condensation, mixing of volatile-rich and -poor reservoirs, planetary accretional volatilization via impacts, and/or magma ocean degassing. While K isotopes have the potential to distinguish these different processes, the current results are still highly debated. A good correlation between the K isotope compositions of four differentiated bodies (Earth, Mars, Moon, and Vesta) and their masses suggests a ubiquitous volatile depletion mechanism during the formation of the terrestrial planets. It is still unknown whether any of the K isotopic variation among chondrites and differentiated bodies can be attributed to inherited signatures of mass-independent isotopic anomalies. 相似文献