Oxygen Isotopic Compositions of Solar Corundum Grains

Oxygen is one of the major rock-forming elements in the solar system and the third most abundant element of the Sun. Oxygen isotopic composition of the Sun, however, is not known due to a poor resolution of astronomical spectroscopic measurements. Several Delta *D17O values have been proposed for th...

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Bibliographic Details
Published in:The Astrophysical journal 2009-11, Vol.706 (1), p.142-147
Main Authors: Makide, Kentaro, Nagashima, Kazuhide, Krot, Alexander N, Huss, Gary R
Format: Article
Language:English
Subjects:
ABUNDANCE
ALKALINE EARTH METALS
ALUMINIUM
ALUMINIUM COMPOUNDS
ALUMINIUM OXIDES
Astronomy
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
CALCIUM
CHALCOGENIDES
CHONDRITES
CONDENSATES
COOLING
CORUNDUM
DIMENSIONLESS NUMBERS
Earth, ocean, space
ELEMENTS
EVAPORATION
EVEN-EVEN NUCLEI
EVEN-ODD NUCLEI
Exact sciences and technology
ISOTOPE RATIO
ISOTOPES
LIGHT NUCLEI
MAIN SEQUENCE STARS
MELTING
METALS
METEORITES
METEOROIDS
MINERALS
NEBULAE
NONMETALS
NUCLEI
OXIDE MINERALS
OXIDES
OXYGEN
OXYGEN 16
OXYGEN 17
OXYGEN COMPOUNDS
OXYGEN ISOTOPES
PHASE TRANSFORMATIONS
SOLAR ACTIVITY
SOLAR NEBULA
SOLAR SYSTEM
SOLAR WIND
STABLE ISOTOPES
STARS
STELLAR ACTIVITY
STELLAR WINDS
STONE METEORITES
SUN
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Summary:Oxygen is one of the major rock-forming elements in the solar system and the third most abundant element of the Sun. Oxygen isotopic composition of the Sun, however, is not known due to a poor resolution of astronomical spectroscopic measurements. Several Delta *D17O values have been proposed for the composition of the Sun based on (1) the oxygen isotopic measurements of the solar wind implanted into metallic particles in lunar soil (< -20 by Hashizume & Chaussidon and ~ +26 by Ireland et al.), (2) the solar wind returned by the Genesis spacecraft (-27 +/- 6 by McKeegan et al.), and (3) the mineralogically pristine calcium-aluminum-rich inclusions (CAIs) (-23.3 +/- 1.9 by Makide et al. and -35 by Gounelle et al.). CAIs are the oldest solar system solids, and are believed to have formed by evaporation, condensation, and melting processes in hot nebular region(s) when the Sun was infalling (Class 0) or evolved (Class 1) protostar. Corundum (Al2O3) is thermodynamically the first condensate from a cooling gas of solar composition. Corundum-bearing CAIs, however, are exceptionally rare, suggesting either continuous reaction of the corundum condensates with a cooling nebular gas and their replacement by hibonite (CaAl12O19) or their destruction by melting together with less refractory condensates during formation of igneous CAIs. In contrast to the corundum-bearing CAIs, isolated micrometer-sized corundum grains are common in the acid-resistant residues from unmetamorphosed chondrites. These grains could have avoided multistage reprocessing during CAI formation and, therefore, can potentially provide constraints on the initial oxygen isotopic composition of the solar nebula, and, hence, of the Sun. Here we report oxygen isotopic compositions of ~60 micrometer-sized corundum grains in the acid-resistant residues from unequilibrated ordinary chondrites (Semarkona (LL3.0), Bishunpur (LL3.1), Roosevelt County 075 (H3.2)) and unmetamorphosed carbonaceous chondrites (Orgueil (CI1), Murray (CM2), and Alan Hills A77307 (CO3.0)) measured with a Cameca ims-1280 ion microprobe. All corundum grains, except two, are 16O-rich ( Delta *D17O = -22.7 +/- 8.5, 2 Delta *s), and compositionally similar to the mineralogically pristine CAIs from the CR carbonaceous chondrites (-23.3 +/- 1.9, 2 Delta *s), and solar wind returned by the Genesis spacecraft (-27 +/- 6, 2 Delta *s). One corundum grain is highly 17O-enriched ( Delta *d17O ~ +60, Delta *d18O ~ -40) and is probably of the pr
ISSN:0004-637X
1538-4357
DOI:10.1088/0004-637X/706/1/142