Molecular Cloud Origin for the Oxygen Isotope Heterogeneity in the Solar System

Molecular Cloud Origin for the Oxygen Isotope Heterogeneity in the Solar System

Meteorites and their components have anomalous oxygen isotopic compositions characterized by large variations in18O/16O and$^{17}O/^{16}O$ratios. On the basis of recent observations of star-forming regions and models of accreting protoplanetary disks, we suggest that these variations may originate i...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2004-09, Vol.305 (5691), p.1763-1766
Hauptverfasser: Yurimoto, Hisayoshi, Kuramoto, Kiyoshi
Format: Artikel
Sprache:eng
Schlagworte:
Accretion disks
Carbon Isotopes
Carbon Monoxide
Chemical composition
Chemistry
Cosmic Dust
Cosmochemistry. Extraterrestrial geology
Earth sciences
Earth, ocean, space
Exact sciences and technology
Fractionation
Gas composition
Geochemistry
Ice
Isotope geochemistry
Isotope geochemistry. Geochronology
Isotopes
Meteorites. Tectites. Impactites
Meteors & meteorites
Molecular clouds
Molecular structure
Observations
Oxygen
Oxygen Isotopes
Photochemistry
Photons
Protoplanetary disks
Silicates
Solar nebulae
Solar System
Solar systems
Star formation
Temperature
Ultraviolet Rays
Water
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Zusammenfassung:Meteorites and their components have anomalous oxygen isotopic compositions characterized by large variations in18O/16O and$^{17}O/^{16}O$ratios. On the basis of recent observations of star-forming regions and models of accreting protoplanetary disks, we suggest that these variations may originate in a parent molecular cloud by ultraviolet photodissociation processes. Materials with anomalous isotopic compositions were then transported into the solar nebula by icy dust grains during the collapse of the cloud. The icy dust grains drifted toward the Sun in the disk, and their subsequent evaporation resulted in the$^{17}O- and ^{18}O-enrichment$of the inner disk gas.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.1100989