Ureilite

Ureilite
— Group —
NWA 4231, an example of an ureilite meteorite
Compositional type	Stony
Type	Achondrite
Class	Primitive achondrite
Subgroups	monomict polymict
Parent body	Unknown (F-type?)
Composition	Olivine-pigeonite

Ureilite is a rare type of stony meteorite that has a unique mineralogical composition very different from that of other stony meteorites. This dark grey or brownish meteorite type is named after the village Novy Urey (Cyrillic: Новый Урей), Mordovia Republic of Russia, where a meteorite of this type fell on 4 September 1886. Notable ureilites are the Novo Urei and the Goalpara, also named for the town in which it landed (Goalpara, Assam India). On 7 October 2008, tiny asteroid 2008 TC₃ entered Earth's atmosphere and exploded an estimated 37 kilometres (23 mi) above the Nubian Desert in Sudan. Fragments of this asteroid were recovered the following December and were found to be ureilite. Scientists have discovered amino acids in meteorite 2008 TC₃ where none were expected, taking into account high temperatures reached in the explosion of about 1000 °C.^[1]

Composition

A geological name for ureilite would be olivine-pigeonite achondrite. Compared to most other meteorites, ureilites tend to have a high percentage of carbon (average 3% by weight) in the form of graphite and nanodiamonds.^[2] The diamonds, which are rarely more than a few micrometres in diameter, are probably the result of high pressure shockwaves produced by collisions of the ureilite parent body with other asteroids. Ureilites can be divided into two subcategories: monomict and polymict. Monomict ureilites are coarse-grained, with olivine usually more abundant than pyroxene. Polymict ureilites are a mixture of clasts of dissimilar composition.

Origin

Unknown. Some groups of meteorites come from a single object (i.e. Mars, Moon, 4 Vesta), but no parent body has been found for the ureilites. Before impacting Earth 2008 TC₃ was identified as an F-type asteroid.^[3]

One theory suggests that ureilites were formed in the interior of a parent body with cumulate crystals that formed crystal layers. Support for this comes from some ureilites in which the grains are aligned in a preferred orientation. Another suggestion is that ureilites represent a residuum of unmelted material after a partial melt liquid was drawn off. Yet other ideas are that they are unprocessed materials which never melted or that they are mixtures of carbonaceous chondrite and basaltic rock melts. It remains unclear whether ureilites originated on different parent bodies or in different regions of a single body. The presence of diamonds, which can form from graphite as a result of severe shock metamorphism, hints at a violent impact history.^[4] By contrast, a 2018 study of the diamond inclusions in 2008 TC₃ concluded that they could only have formed over a relatively long period of time at high pressure, suggesting that "the ureilite parent body was a Mercury- to Mars-sized planetary embryo."^[5]

See also

• Glossary of meteoritics
• Meteorite classification

References

1. "Life's Building Blocks Found on Surprising Meteorite". Space.com. Retrieved 2016-05-10.
2. Norton, O. Richard (2002-03-11). The Cambridge Encyclopedia of Meteorites. Cambridge University Press. ISBN 9780521621434.
3. P. Jenniskens; et al. (2009-03-26). "The impact and recovery of asteroid 2008 TC3". Nature. 458 (7237, number 458): 485–488. Bibcode:2009Natur.458..485J. doi:10.1038/nature07920. PMID 19325630. Published in Letters to Nature.
4. "ureilite". www.daviddarling.info. Retrieved 2016-05-10.
5. Nabiei, Farhang; Badro, James; Dennenwaldt, Teresa; Oveisi, Emad; Cantoni, Marco; Hébert, Cécile; El Goresy, Ahmed; Barrat, Jean-Alix; Gillet, Philippe (2018). "A large planetary body inferred from diamond inclusions in a ureilite meteorite". Nature Communications. 9 (1): 1327. Bibcode:2018NatCo...9.1327N. doi:10.1038/s41467-018-03808-6. ISSN 2041-1723. PMC 5904174. PMID 29666368. The composition and morphology of the inclusions can only be explained if the formation pressure was higher than 20 GPa. Such pressures suggest that the ureilite parent body was a Mercury- to Mars-sized planetary embryo.