The origin of the moon and the early history of the earth - a chemical model. Part 2: The earth
Journal Article
·
· Geochimica et Cosmochimica Acta; (USA)
- Univ. Bayreuth (Germany)
The geochemical implications for the earth of a giant impact model for the origin of the earth-moon system are discussed, using a mass balance between three components: the proto-earth, the Impactor, and a late veneer. It is argued that the proto-earth accretes from material resembling a high temperature condensate from the solar nebula. Core formation takes place under very reducing conditions, resulting in the mantle of the proto-earth being completely stripped of all elements more siderophile than Fe, and partly depleted in the barely siderophile elements V, Cr, and perhaps Si. The Impactor then collides with the proto-earth, causing vaporisation of both the Impactor and a substantial portion of the earth's mantle. Most of this material recondenses to the earth, but some forms the moon. The Impactor adds most of the complement of the siderophile elements of the present mantle in an oxidized form. The oxidation state of the mantle is set near to its present, oxidized level. Finally, the addition of a late veneer, of composition similar to that of the H-group ordinary chondrites, accounts for the complement of the highly siderophile elements of the present mantle. The model accounts at least semi-quantitatively for the siderophile element abundances of the present mantle. Implications for the composition of the earth's core are discussed; the model predicts that neither S, O, nor Si should be present in sufficient quantities to provide the required light element in the core, whose identity, therefore, remains enigmatic.
- OSTI ID:
- 5597978
- Journal Information:
- Geochimica et Cosmochimica Acta; (USA), Journal Name: Geochimica et Cosmochimica Acta; (USA) Vol. 55:4; ISSN GCACA; ISSN 0016-7037
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
58 GEOSCIENCES
580000* -- Geosciences
640107 -- Astrophysics & Cosmology-- Planetary Phenomena
71 CLASSICAL AND QUANTUM MECHANICS
GENERAL PHYSICS
ABUNDANCE
CHALCOGENIDES
CHEMICAL COMPOSITION
CHEMICAL REACTIONS
CHEMISTRY
CHONDRITES
CHROMIUM
COMPARATIVE EVALUATIONS
COSMOLOGICAL MODELS
EARTH MANTLE
EARTH PLANET
ELEMENT ABUNDANCE
ELEMENTS
GEOCHEMISTRY
GEOLOGIC HISTORY
IRON
LUNAR MATERIALS
MASS BALANCE
MATERIALS
MATHEMATICAL MODELS
METALS
METEORITES
MINERALS
MOON
NEBULAE
ORIGIN
OXIDATION
OXIDE MINERALS
OXIDES
OXYGEN COMPOUNDS
PLANETARY EVOLUTION
PLANETS
SATELLITES
SILICA
SILICON COMPOUNDS
SILICON OXIDES
SOLAR NEBULA
SOLAR SYSTEM EVOLUTION
STONE METEORITES
TRANSITION ELEMENTS
VANADIUM
580000* -- Geosciences
640107 -- Astrophysics & Cosmology-- Planetary Phenomena
71 CLASSICAL AND QUANTUM MECHANICS
GENERAL PHYSICS
ABUNDANCE
CHALCOGENIDES
CHEMICAL COMPOSITION
CHEMICAL REACTIONS
CHEMISTRY
CHONDRITES
CHROMIUM
COMPARATIVE EVALUATIONS
COSMOLOGICAL MODELS
EARTH MANTLE
EARTH PLANET
ELEMENT ABUNDANCE
ELEMENTS
GEOCHEMISTRY
GEOLOGIC HISTORY
IRON
LUNAR MATERIALS
MASS BALANCE
MATERIALS
MATHEMATICAL MODELS
METALS
METEORITES
MINERALS
MOON
NEBULAE
ORIGIN
OXIDATION
OXIDE MINERALS
OXIDES
OXYGEN COMPOUNDS
PLANETARY EVOLUTION
PLANETS
SATELLITES
SILICA
SILICON COMPOUNDS
SILICON OXIDES
SOLAR NEBULA
SOLAR SYSTEM EVOLUTION
STONE METEORITES
TRANSITION ELEMENTS
VANADIUM