R. D. Ash scite author profile

High-precision magnesium isotope measurements of whole chondrules from the Allende carbonaceous chondrite meteorite show that some aluminum-rich Allende chondrules formed at or near the time of formation of calcium-aluminum-rich inclusions and that some others formed later and incorporated precursors previously enriched in magnesium-26. Chondrule magnesium-25/magnesium-24 correlates with [magnesium]/[aluminum] and size, the aluminum-rich, smaller chondrules being the most enriched in the heavy isotopes of magnesium. These relations imply that high gas pressures prevailed during chondrule formation in the solar nebula.

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The origin of chondritic macromolecular organic matter: A carbon and nitrogen isotope study

Alexander

Russell

Arden

et al. 1998

Meteorit & Planetary Scien

183

176

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Abstract-The N and C abundances and isotopic compositions of acid-insoluble carbonaceous material in thirteen primitive chondrites (five unequilibrated ordinary chondrites, three CM chondrites, three enstatite chondrites, a CI chondrite and a CR chondrite) have been measured by stepped combustion. While the range of C isotopic compositions observed is only 413C = 30%0, the N isotopes range from 6I5N = 4 0 to 260%0.After correction for metamorphism, presolar nanodiamonds appear to have made up a fairly constant 3 -4 wt% of the insoluble C in all the chondrites studied. The apparently similar initial presolar nanodiamond to organic C ratios, and the correlations of elemental and isotopic compositions with metamorphic indicators in the ordinary and enstatite chondrites, suggest that the chondrites all accreted similar organic material. This original material probably most closely resembles that now found in Renazzo and Semarkona. These two meteorites have almost M-shaped N isotope release profiles that can be explained most simply by the superposition of two components, one with a composition between 615N = -20 and 40%0 and a narrow combustion interval, the other having a broader release profile and a composition of d15N = 260%0. Although isotopically more subdued, the CI and the three CM chondrites all appear to show vestiges of this M-shaped profile. How and where the components in the acid-insoluble organics formed remains poorly constrained. The small variation in nanodiamond to organic C ratio between the chondrite groups limits the local synthesis of organic matter in the various chondrite formation regions to at most 30%. The most IsN-rich material probably formed in the interstellar medium, and the fraction of organic N in Renazzo in this material ranges from 40 to 70%. The isotopically light component may have formed in the solar system, but the limited range in nanodiamond to total organic C ratios in the chondrite groups is consistent with most of the organic material being presolar. INTRODUCTIONThe majority of C in primitive chondritic meteorites is present as organic material. The synthesis of this material is poorly understood, and none of the formation models proposed thus far have been able to explain all of the observed chemical and isotopic features. The organic material in CI and CM chondrites, the most extensively studied of the chondrite groups, can be broadly divided into a soluble fraction and a much more abundant (70-95%) insoluble fraction (Becker and Epstein, 1982). The soluble fraction is a mixture that includes amino acids as well as aliphatic and aromatic hydrocarbons.The insoluble fraction is a complex macromolecular material, rich in polycyclic aromatic hydrocarbons (PAH), which has often been described as kerogen-like.For many years, the most popular hypothesis for the origin of organic material in CI and CM carbonaceous chondrites was via Fischer-Tropsch-type (FTT) synthesis in the solar nebula (e.g., Hayatsu and Anders, 1981). It was envisaged that, as the nebula cooled to 30WOO K ...

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Fluid Flow in Chondritic Parent Bodies: Deciphering the Compositions of Planetesimals

Young

Ash

England

et al. 1999

Science

176

154

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Alteration of the Allende meteorite caused shifts in oxygen isotope ratios along a single mass fractionation line. If alteration was caused by aqueous fluid, the pattern of oxygen isotope fractionation can be explained only by flow of reactive water down a temperature gradient. Down-temperature flow of aqueous fluid within planetesimals is sufficient to explain the mineralogical and oxygen isotopic diversity among CV, CM, and CI carbonaceous chondrites and displacement of the terrestrial planets from the primordial slope 1. 00 line on the oxygen three-isotope plot.

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Early formation of evolved asteroidal crust

Day

Ash

Liu

et al. 2009

Nature

128

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Mechanisms for the formation of crust on planetary bodies remain poorly understood. It is generally accepted that Earth's andesitic continental crust is the product of plate tectonics, whereas the Moon acquired its feldspar-rich crust by way of plagioclase flotation in a magma ocean. Basaltic meteorites provide evidence that, like the terrestrial planets, some asteroids generated crust and underwent large-scale differentiation processes. Until now, however, no evolved felsic asteroidal crust has been sampled or observed. Here we report age and compositional data for the newly discovered, paired and differentiated meteorites Graves Nunatak (GRA) 06128 and GRA 06129. These meteorites are feldspar-rich, with andesite bulk compositions. Their age of 4.52 +/- 0.06 Gyr demonstrates formation early in Solar System history. The isotopic and elemental compositions, degree of metamorphic re-equilibration and sulphide-rich nature of the meteorites are most consistent with an origin as partial melts from a volatile-rich, oxidized asteroid. GRA 06128 and 06129 are the result of a newly recognized style of evolved crust formation, bearing witness to incomplete differentiation of their parent asteroid and to previously unrecognized diversity of early-formed materials in the Solar System.

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Isotopic homogeneity of iron in the early solar nebula

Zhu

Guo

O’Nions

et al. 2001

Nature

132

120

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The chemical and isotopic homogeneity of the early solar nebula, and the processes producing fractionation during its evolution, are central issues of cosmochemistry. Studies of the relative abundance variations of three or more isotopes of an element can in principle determine if the initial reservoir of material was a homogeneous mixture or if it contained several distinct sources of precursor material. For example, widespread anomalies observed in the oxygen isotopes of meteorites have been interpreted as resulting from the mixing of a solid phase that was enriched in 16O with a gas phase in which 16O was depleted, or as an isotopic 'memory' of Galactic evolution. In either case, these anomalies are regarded as strong evidence that the early solar nebula was not initially homogeneous. Here we present measurements of the relative abundances of three iron isotopes in meteoritic and terrestrial samples. We show that significant variations of iron isotopes exist in both terrestrial and extraterrestrial materials. But when plotted in a three-isotope diagram, all of the data for these Solar System materials fall on a single mass-fractionation line, showing that homogenization of iron isotopes occurred in the solar nebula before both planetesimal accretion and chondrule formation.

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Metallic phases and siderophile elements in main group ureilites: Implications for ureilite petrogenesis

Goodrich

Ash

Orman

et al. 2013

Geochimica et Cosmochimica Acta

113

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R. D. Ash

Modeling fractional crystallization of group IVB iron meteorites

Origin of felsic achondrites Graves Nunataks 06128 and 06129, and ultramafic brachinites and brachinite-like achondrites by partial melting of volatile-rich primitive parent bodies

The Formation of Chondrules at High Gas Pressures in the Solar Nebula

The origin of chondritic macromolecular organic matter: A carbon and nitrogen isotope study

Fluid Flow in Chondritic Parent Bodies: Deciphering the Compositions of Planetesimals

Early formation of evolved asteroidal crust

Isotopic homogeneity of iron in the early solar nebula

Metallic phases and siderophile elements in main group ureilites: Implications for ureilite petrogenesis

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