Molybdenum isotope anomalies in meteorites: Constraints on solar nebula evolution and origin of the Earth

When the Earth had grown to the present mass through accretion of the planetesimals in the solar nebula, the Earth was surrounded by a dense primordial atmosphere which was mainly composed of hydrogen and helium (Hayashi et al. 1979). Mass of the atmosphere was about 1×1026 g. We investigate the dissipation of this atmosphere due to the irradiation of solar EUV. The effect of solar wind is neglected. We assume that the flow of the escaping gas is spherically symmetric and steady. We impose the boundary condition that the flow velocity go through a sonic point. The results show that the primordial atmosphere is dissipated within a period of 5 × 108 yrs, which is the upper limit imposed from the theory of the origin of the present terrestrial atmosphere (Hamano and Ozima 1978), as far as the solar EUV flux is more than two hundred times as large as the present one. In this case, the rare gases contained in the promordial atmosphere are also dissipated owing to the drag effect (Sekiya et al. 1980).

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The relation of mantle heterogeneity to the bulk composition and origin of the Earth

Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences ◽

10.1098/rsta.1980.0207 ◽

1980 ◽

Vol 297 (1431) ◽

pp. 139-146 ◽

Cited By ~ 3

Keyword(s):

Heat Flow ◽

Oxygen Isotope ◽

Solar Nebula ◽

Bulk Composition ◽

Outer Core ◽

The Sun ◽

Mantle Heterogeneity ◽

Oxygen Isotope Ratios ◽

The Earth ◽

Reduced State

The heterogeneity of the mantle can be viewed in the context of models for accretion of the terrestrial planets from the solar nebula. Oxygen isotope ratios and mineralogy indicate the existence of hot planetesimals of diverse compositions. Assuming that nebular condensates range from a reduced state near the Sun to an oxidized state near Jupiter, a new model is proposed for heterogeneous accretion of the Earth beginning with hot, reduced condensates and ending with cool, oxidized condensates. The Ganapathy—Anders cosmochemical model for the bulk composition of the Earth was tested by summing measured compositions for the three outer zones and likely compositions for the inner zones. Revisions are suggested, including reduction of the content of the early condensate from that suggested by taking [U] « 30 ng/g, as suggested by naive interpretation of the heat flow. Elements that enter magma in preference to pyroxene or olivine are mainly confined to the outer 200 km. Elements that are chalcophilic under reduced conditions may be partly in the outer core. Hydrogen loss should result in an inward wave of oxidation, and may result in conversion of carbon to CO 2 .

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Geochemical arguments for an Earth-like Moon-forming impactor

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2013.0244 ◽

2014 ◽

Vol 372 (2024) ◽

pp. 20130244 ◽

Cited By ~ 80

Author(s):

Nicolas Dauphas ◽

Christoph Burkhardt ◽

Paul H. Warren ◽

Teng Fang-Zhen

Keyword(s):

Isotopic Composition ◽

Solar Nebula ◽

Building Blocks ◽

Inversion Method ◽

Stage Model ◽

The Moon ◽

Two Stage ◽

Geochemical Evidence ◽

Giant Impact ◽

The Earth

Geochemical evidence suggests that the material accreted by the Earth did not change in nature during Earth's accretion, presumably because the inner protoplanetary disc had uniform isotopic composition similar to enstatite chondrites, aubrites and ungrouped achondrite NWA 5363/5400. Enstatite meteorites and the Earth were derived from the same nebular reservoir but diverged in their chemical evolutions, so no chondrite sample in meteorite collections is representative of the Earth's building blocks. The similarity in isotopic composition (Δ 17 O, ε 50 Ti and ε 54 Cr) between lunar and terrestrial rocks is explained by the fact that the Moon-forming impactor came from the same region of the disc as other Earth-forming embryos, and therefore was similar in isotopic composition to the Earth. The heavy δ 30 Si values of the silicate Earth and the Moon relative to known chondrites may be due to fractionation in the solar nebula/protoplanetary disc rather than partitioning of silicon in Earth's core. An inversion method is presented to calculate the Hf/W ratios and ε 182 W values of the proto-Earth and impactor mantles for a given Moon-forming impact scenario. The similarity in tungsten isotopic composition between lunar and terrestrial rocks is a coincidence that can be explained in a canonical giant impact scenario if an early formed embryo (two-stage model age of 10–20 Myr) collided with the proto-Earth formed over a more protracted accretion history (two-stage model age of 30–40 Myr).

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On the Growth of the Earth-Moon System

Highlights of Astronomy ◽

10.1017/s1539299600002203 ◽

1974 ◽

Vol 3 ◽

pp. 469-473

Author(s):

F. L. Whipple

Keyword(s):

Solar Nebula ◽

Low Density ◽

Differentiation Process ◽

The Moon ◽

Moon System ◽

Hypervelocity Impacts ◽

The Earth ◽

Refractory Minerals ◽

Gravitational Capture ◽

Two Bodies

This paper elaborates the postulate that the Earth and Moon became a binary system during their accretional development and that the Moon’s growth was essentially completed before the assumed solar nebula dissipated. The solar nebula was still hot enough at the formation of the two bodies that both consisted largely of the refractory and relatively low-density minerals now characteristic of the Moon. During the subsequent condensation, agglomeration and accretion of siderophile and more volatile higher density minerals, the Earth grew very much faster than the Moon because of (a) its much greater gravitational capture area coupled with retention by a sizeable atmosphere and (t>) the Moon’s velocity, with respect to the solar nebula, which produced a wind that aerodynamically blew away volatiles and smaller debris resulting from hypervelocity impacts of larger planetesimals. This ‘impact differentiation’ process favored the retention of the refractory minerals on the Moon (Figure 1). The Moon’s surprisingly high moment of inertia follows naturally from the basic postulate.

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Origins and Early Evolution of the Atmosphere and the Oceans

Geochemical Perspectives ◽

10.7185/geochempersp.9.2 ◽

2020 ◽

Vol 9 (2) ◽

pp. 135-313

Author(s):

Bernard Marty

Keyword(s):

Solar System ◽

Solar Nebula ◽

Noble Gases ◽

Building Blocks ◽

Anthropogenic Activity ◽

Outer Solar System ◽

Volatile Elements ◽

Isotopic Signatures ◽

Early Atmosphere ◽

The Earth

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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8. Genetic Relations among Meteorites and Planets

International Astronomical Union Colloquium ◽

10.1017/s0252921100070548 ◽

1977 ◽

Vol 39 ◽

pp. 545-550 ◽

Cited By ~ 1

Author(s):

R. N. Clayton

Keyword(s):

Solar Nebula ◽

Major Element ◽

Carbonaceous Chondrite ◽

Carbonaceous Chondrites ◽

Powerful Method ◽

Ordinary Chondrites ◽

Element Abundances ◽

The Earth ◽

Enstatite Chondrites ◽

Source Materials

On the basis of 180/160 and 170/160 ratios, meteorites and planets can be grouped into at least nine categories, as follows (in order of increasing 1°0): (1) type L and LL ordinary chondrites; (2) type H ordinary chondrites, type HE irons, and CI carbonaceous chondrites; (3) the nakhlites and Shergotty; (4) the earth, moon, and enstatite chondrites and achondrites; (5) basaltic achondrites, hypersthene achondrites, mesosiderites, pallasites and type IRB irons; (6) the ureilites; (7) C2 carbonaceous chondrite matrix, Bencubbin, Weatherford, and Kakangari; (8) C3 carbonaceous chondrites; (9) pallasites Eagle Station and Itzawisis. Objects of one category cannot be derived by fractionation or differentiation from the source materials of any other category, but must represent samples of different regions of an i nhomogeneous solar nebula. The isotopic classification, together with major-element abundances, provides a powerful method for recognition of interrelationships of the various meteorites and their parent bodies.

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Nucleosynthetic molybdenum isotope anomalies in iron meteorites – new evidence for thermal processing of solar nebula material

Earth and Planetary Science Letters ◽

10.1016/j.epsl.2017.05.001 ◽

2017 ◽

Vol 473 ◽

pp. 215-226 ◽

Cited By ~ 33

Author(s):

Graeme M. Poole ◽

Mark Rehkämper ◽

Barry J. Coles ◽

Tatiana Goldberg ◽

Caroline L. Smith

Keyword(s):

Thermal Processing ◽

Solar Nebula ◽

Iron Meteorites ◽

Molybdenum Isotope ◽

New Evidence

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The motion of a lunar orbiter

Symposium - International Astronomical Union ◽

10.1017/s0074180900105686 ◽

1966 ◽

Vol 25 ◽

pp. 373

Author(s):

Y. Kozai

Keyword(s):

Degrees Of Freedom ◽

Dimensional Space ◽

Artificial Satellite ◽

Equations Of Motion ◽

Triaxial Ellipsoid ◽

The Moon ◽

Secular Motion ◽

The Earth ◽

Close Satellite ◽

The Mean

The motion of an artificial satellite around the Moon is much more complicated than that around the Earth, since the shape of the Moon is a triaxial ellipsoid and the effect of the Earth on the motion is very important even for a very close satellite.The differential equations of motion of the satellite are written in canonical form of three degrees of freedom with time depending Hamiltonian. By eliminating short-periodic terms depending on the mean longitude of the satellite and by assuming that the Earth is moving on the lunar equator, however, the equations are reduced to those of two degrees of freedom with an energy integral.Since the mean motion of the Earth around the Moon is more rapid than the secular motion of the argument of pericentre of the satellite by a factor of one order, the terms depending on the longitude of the Earth can be eliminated, and the degree of freedom is reduced to one.Then the motion can be discussed by drawing equi-energy curves in two-dimensional space. According to these figures satellites with high inclination have large possibilities of falling down to the lunar surface even if the initial eccentricities are very small.The principal properties of the motion are not changed even if plausible values ofJ3andJ4of the Moon are included.This paper has been published in Publ. astr. Soc.Japan15, 301, 1963.

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