An integrated mineralogical, petrologic and isotopic study of ureilites
The ureilites are essentially carbon-bearing, ultramafic meteorites that comprise the second largest of the achondrite meteorite groups. The mineral assemblage, petrography and certain aspects of mineral chemistry that the ureilites display suggest a differentiated and igneous petrogenetic history....
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| Format: | Thesis |
| Language: | unknown |
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2003
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| Online Access: | https://oro.open.ac.uk/63222/ https://oro.open.ac.uk/63222/1/272393.pdf https://doi.org/10.21954/ou.ro.0000f6f6 |
| Summary: | The ureilites are essentially carbon-bearing, ultramafic meteorites that comprise the second largest of the achondrite meteorite groups. The mineral assemblage, petrography and certain aspects of mineral chemistry that the ureilites display suggest a differentiated and igneous petrogenetic history. However, in terms of oxygen isotope compositions and high carbon contents they appear similar to the primitive and unprocessed carbonaceous chondrites; evidence which has been taken to suggest a genetic link between the ureilites and the carbonaceous chondrites. Ureilites may be divided into four distinct groups on the basis of constant Δ 17 O compositions, suggesting formation on four parent bodies or four separate regions on a single parent body. Samples analysed herein have been taken from two oxygen groups to gain a better understanding of inter-/intra-group relationships and the petrogenetic history of the parent body (ies). The first detailed mineralogical and petrological examination of 17 ureilite samples has been carried out in combination with high-resolution stepped combustion analyses of 11 of the samples to determine carbon form, abundance and isotopic composition. High- resolution stepped combustion analyses have also been carried out for the first time on 10 samples from Disko Island, Greenland and 3 terrestrial graphites. Results from Disko Island samples (potential terrestrial analogues to the ureilites) suggest that carbon isotopic compositions of lithologies that have undergone reduction reactions and thermal metamorphism will be little changed compared with the original composition. This poses a major problem to models of ureilite petrogenesis that suggest the carbonaceous chondrites as the ureilite progenitor material. The carbon abundance and isotopic composition of ureilites may be affected by fluid flow on the parent body; perhaps as a secondary process resulting from the (re)mobilisation of carbon-bearing fluids (formed though reduction reactions) during a catastrophic shock event. Indication ... |
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