Ordinary chondrite
In the following article, we will explore Ordinary chondrite from a deep and detailed perspective, covering all relevant aspects related to this topic. From its history and evolution to its impact on today's society, we will analyze the different points of view and opinions of experts on the subject. Additionally, we will examine case studies and concrete examples to illustrate their importance and relevance today. With updated information and relevant data, this article seeks to provide a complete and enriching vision about Ordinary chondrite, with the purpose of informing and educating our readers about this topic that is so relevant today.
| Ordinary chondrite | |
|---|---|
| — Class — | |
 Ordinary chondrite NWA 869 | |
| Compositional type | Stony |
| Type | Chondrite |
| Parent body | unknown |
| Alternative names | O chondrites |
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The ordinary chondrites (sometimes called the O chondrites) are a class of stony chondritic meteorites. They are by far the most numerous group, comprising 87% of all finds.[1] Hence, they have been dubbed "ordinary". The ordinary chondrites are thought to have originated from three parent asteroids, with the fragments making up the H chondrite, L chondrite and LL chondrite groups respectively.[2]
Origin
It is suspected that they are not representative of typical asteroid parent bodies, but rather of a select few which are advantageously placed to send impact fragments to Earth-crossing orbits. Such positions are e.g. near Kirkwood gaps and/or secular resonances in the main asteroid belt. In fact, only the one rather insignificant asteroid 3628 Božněmcová has been identified to have a spectrum close to the ordinary chondrites.
A probable parent body of the H chondrites (comprising about 46% of the ordinary chondrites) is 6 Hebe, but its spectrum is dissimilar due to what is likely a metal impact melt component.[3]
It is likely that the ordinary chondrites comprise a detailed sample of but a few select asteroids which happen to have been in the right place at the right time to send many fragments toward Earth at the present moment in solar system history. On the other hand, observations of 243 Ida by the Galileo spacecraft found weathering of Ida's surface, and the reflection spectra of freshly exposed parts of the surface resembled that of OC meteorites, while the older regions matched the spectra of common S-type asteroids.
Chemical composition
The ordinary chondrites comprise three mineralogically and chemically distinct groupings. They differ in the amount of total iron, of iron metal and iron oxide in the silicates:[4]
- The H chondrites have the Highest total iron, high metal, but lower iron oxide (Fa[clarification needed]) in the silicates
- The L chondrites have Lower total iron, lower metal, but higher iron oxide (Fa) in the silicates
- The LL chondrites have Low total iron and Low metal, but the highest iron oxide content (Fa) in the silicates
See also
References
- ^ Grady, Monica (2022). "Meteorites". The Catalogue of Meteorites. Natural History Museum. doi:10.5519/tqfuwle7. Retrieved 28 May 2020.
- ^ David Kring (21 November 2013). "Asteroid Initiative Workshop Cosmic Explorations Speakers Session". NASA (via YouTube). Retrieved 16 February 2019.
- ^ Gaffey, M. J.; Gilbert, S. L. (1998). "Asteroid 6 Hebe: The probable parent body of the H-Type ordinary chondrites and the IIE iron meteorites". Meteoritics & Planetary Science. 33 (6): 1281–1295. Bibcode:1998M&PS...33.1281G. doi:10.1111/j.1945-5100.1998.tb01312.x.
- ^ "Classification – Stony Meteorites – Ordinary tauch.Chondrites". www.meteorite.fr. Retrieved 10 August 2017.
External links
- The Catalogue of Meteorites
- A Pictorial of Ordinary Chondrites - Meteorites Australia
- Gallery of Ordinary Chondrites by James St. John, a geologist at Ohio State University