Chondrite

For trace fossil ichnogenus, see Chondrites (genus).
Not to be confused with Chondrodite.
Chondrite
 Type 

A specimen of the NWA 869 chondrite (type L4-6), showing chondrules and metal flakes
Compositional type Stony
Parent body Small to medium asteroids that were never part of a body large enough to undergo melting and planetary differentiation.
Petrologic type 3–6
Total known specimens Over 27,000

Chondrites are stony (non-metallic) meteorites that have not been modified due to melting or differentiation of the parent body.[1][2] They are formed when various types of dust and small grains that were present in the early solar system accreted to form primitive asteroids. They are the most common type of meteorite that falls to Earth with estimates for the proportion of the total fall that they represent varying between 85.7%[3] and 86.2%.[4] Their study provides important clues for understanding the origin and age of the Solar System, the synthesis of organic compounds, the origin of life or the presence of water on Earth. One of their characteristics is the presence of chondrules, which are round grains formed by distinct minerals, that normally constitute between 20% and 80% of a chondrite by volume.[5]

Chondrites can be differentiated from iron meteorites due to their low iron and nickel content. Other non-metallic meteorites, achondrites, which lack chondrules, were formed more recently.[6]

There are currently over 27,000 chondrites in the world's collections. The largest individual stone ever recovered, weighing 1770 kg, was part of the Jilin meteorite shower of 1976. Chondrite falls range from single stones to extraordinary showers consisting of thousands of individual stones, as occurred in the Holbrook fall of 1912, where an estimated 14,000 stones rained down on northern Arizona.

Origin and history

Chondrites were formed by the accretion of particles of dust and grit present in the primitive Solar System which gave rise to asteroids over 4.55 billion years ago. These asteroid parent bodies of chondrites are (or were) small to medium-sized asteroids that were never part of any body large enough to undergo melting and planetary differentiation. Dating using 206Pb/204Pb gives an estimated age of 4,566.6 ± 1.0 Ma,[7] matching ages for other chronometers. Another indication of their age is the fact that the abundance of non-volatile elements in chondrites is similar to that found in the atmosphere of the Sun and other stars in our galaxy.[8] Although chondritic asteroids never became hot enough to melt based upon internal temperatures, many of them reached high enough temperatures that they experienced significant thermal metamorphism in their interiors. The source of the heat was most likely energy coming from the decay of short-lived radioisotopes (half-lives less than a few million years) that were present in the newly formed solar system, especially 26Al and 60Fe, although heating may have been caused by impacts onto the asteroids as well. Many chondritic asteroids also contained significant amounts of water, possibly due to the accretion of ice along with rocky material. As a result, many chondrites contain hydrous minerals, such as clays, that formed when the water interacted with the rock on the asteroid in a process known as aqueous alteration. In addition, all chondritic asteroids were affected by impact and shock processes due to collisions with other asteroids. These events caused a variety of effects, ranging from simple compaction to brecciation, veining, localized melting, and formation of high-pressure minerals. The net result of these secondary thermal, aqueous, and shock processes is that only a few known chondrites preserve in pristine form the original dust, chondrules, and inclusions from which they formed.

Protoplanetary disk: particles of dust and grit collide and accrete forming planets or asteroids.
Chondrules in chondrite from the Bjurböle meteorite.[9]
Chondrules in chondrite from the Grassland meteor.[10]

Characteristics

Prominent among the components present in chondrites are the enigmatic chondrules, millimetre-sized spherical objects that originated as freely floating, molten or partially molten droplets in space; most chondrules are rich in the silicate minerals olivine and pyroxene. Chondrites also contain refractory inclusions (including Ca-Al Inclusions), which are among the oldest objects to form in the solar system, particles rich in metallic Fe-Ni and sulfides, and isolated grains of silicate minerals. The remainder of chondrites consists of fine-grained (micrometre-sized or smaller) dust, which may either be present as the matrix of the rock or may form rims or mantles around individual chondrules and refractory inclusions. Embedded in this dust are presolar grains, which predate the formation of our solar system and originated elsewhere in the galaxy. The chondrites have distinct texture, composition and mineralogy and their origin continues to be the object of some debate.[11] The scientific community generally accepts that these spheres were formed by the action of a shock wave that passed through the Solar System, although there is little agreement as to the cause of this shock wave.[12] An article published in 2005 proposed that the gravitational instability of the gaseous disk that Jupiter formed from generated a shock wave with a velocity of more than 10 km/s, which resulted in the formation of the chondrules.[13]

Chondrite classification

Chondrites are divided into about 15 distinct groups (see Meteorites classification) on the basis of their mineralogy,[14] bulk chemical composition, and oxygen isotope compositions[15] (see below). The various chondrite groups likely originated on separate asteroids or groups of related asteroids. Each chondrite group has a distinctive mixture of chondrules, refractory inclusions, matrix (dust), and other components and a characteristic grain size. Other ways of classifying chondrites include weathering[16] and shock.[17]

Chondrites can also be categorized according to their petrologic type, which is the degree to which they were thermally metamorphosed or aqueously altered (they are assigned a number between 1 and 7). The chondrules in a chondrite that is assigned a "3" have not been altered. Larger numbers indicate an increase in thermal metamorphosis up to a maximum of 7, where the chondrules have been destroyed. Numbers lower than 3 are given to chondrites whose chondrules have been changed by the presence of water, down to 1, where the chondrules have been obliterated by this alteration.

A synthesis of the various classification schemes is provided in the table below.[18]

Type Subtype Distinguishing features/Chondrule character Letter designation[19]
Enstatite chondrites Abundant E3, EH3, EL3
Distinct E4, EH4, EL4
Less distinct E5, EH5, EL5
Indistinct E6, EH6, EL6
Melted E7, EH7, EL7
Ordinary chondrites H Abundant H3-H3,9
Distinct H4
Less distinct H5
Indistinct H6
Melted H7
L Abundant L3-L3,9
Distinct L4
Less distinct L5
Indistinct L6
Melted L7
LL Abundant LL3-LL3,9
Distinct LL4
Less distinct LL5
Indistinct LL6
Melted LL7
Carbonaceous chondrites Ivuna Phylosilicates, Magnetite CI
Mighei Phylosilicates, Olivine CM1-CM2
Vigarano Olivines rich in Fe, Ca minerals and Al CV2-CV3.3
Renazzo Phylosilicates, Olivine, Pyroxene, metals CR
Ornans Olivine, Pyroxene, metals, Ca minerals and Al CO3-CO3.7
Karoonda Olivine, Ca minerals and Al CK
Bencubbin Pyroxene, metals CB
High Iron[20] Pyroxene, metals, Olivine CH
Kakangari-type     K
Rumurutiites   Olivine, Pyroxenes, Plagioclase, Sulfides R

Enstatite chondrites

The Saint Sauveur enstatite chondrite (EH5).
Main article: Enstatite chondrite

Enstatite chondrites (also known as E-type chondrites) are a rare form of meteorite thought to comprise only about 2% of the chondrites that fall to Earth.[21] Only about 200 E-Type chondrites are currently known.[21] The majority of enstatite chondrites have either been recovered in Antarctica or have been collected by the American National Weather Association. They tend to be high in the mineral enstatite (MgSiO3), from which they derive their name.[21] E-type chondrites are among the most chemically reduced rocks known, with most of their iron taking the form of metal or sulfide rather than as an oxide. This suggests that they were formed in an area that lacked oxygen, probably within the orbit of Mercury.[22]

Ordinary chondrites

Phnom Penh Chondrite L6 – 1868

Ordinary chondrites are by far the most common type of meteorite to fall to Earth: about 80% of all meteorites and over 90% of chondrites are ordinary chondrites.[11] They contain abundant chondrules, sparse matrix (10–15% of the rock), few refractory inclusions, and variable amounts of Fe-Ni metal and troilite (FeS). Their chondrules are generally in the range of 0.5 to 1 mm in diameter. Ordinary chondrites are distinguished chemically by their depletions in refractory lithophile elements, such as Ca, Al, Ti, and rare earths, relative to Si, and isotopically by their unusually high 17O/16O ratios relative to 18O/16O compared to Earth rocks. Most, but not all, ordinary chondrites have experienced significant degrees of metamorphism, having reached temperatures well above 500 °C on the parent asteroids. They are divided into three groups, which have different amounts of metal and different amounts of total iron:

An example of this group is the NWA 869 meteorite.

Carbonaceous chondrites

Carbonaceous chondrite CV3 that fell in Mexico in 1969 (weight 520 g)

Carbonaceous chondrites (also known as C-type chondrites) make up less than 5% of the chondrites that fall on earth.[24] They are characterized by the presence of carbon compounds, including amino acids.[25] They are thought to have been formed the farthest from the sun of any of the chondrites as they have the highest proportion of volatile compounds.[3] Another of their main characteristics is the presence of water or of minerals that have been altered by the presence of water.

There are many groups of carbonaceous chondrites, but most of them are distinguished chemically by enrichments in refractory lithophile elements relative to Si and isotopically by unusually low 17O/16O ratios relative to 18O/16O compared to Earth rocks. All groups of carbonaceous chondrites except the CH group are named for a characteristic type specimen:

Kakangari chondrites

Three chondrites form what is known as the K (Kakangari type) grouplet,[26] They are characterized by large amounts of dusty matrix and oxygen isotope compositions similar to carbonaceous chondrites, highly reduced mineral compositions and high metal abundances (6% to 10% by volume) that are most like enstatite chondrites, and concentrations of refractory lithophile elements that are most like ordinary chondrites.

Many of their other characteristics are similar to the O, E and C chondrites.[27]

Rumuruti chondrites

R (Rumuruti type) chondrites are a very rare group, with only one documented fall out of almost 900 documented chondrite falls. They have a number of properties in common with ordinary chondrites, including similar types of chondrules, few refractory inclusions, similar chemical composition for most elements, and the fact that 17O/16O ratios are anomalously high compared to Earth rocks. However, there are significant differences between R chondrites and ordinary chondrites: R chondrites have much more dusty matrix material (about 50% of the rock); they are much more oxidized, containing little metallic Fe-Ni; and their enrichments in 17O are higher than those of ordinary chondrites. Nearly all the metal they contain is oxidized or in the form of sulfides. They contain fewer chondrules than the E chondrites, and appear to come from an asteroid's regolith.[28]

Composition

Because chondrites accumulated from material that formed very early in the history of the solar system, and because chondritic asteroids did not melt, they have very primitive compositions. "Primitive," in this sense, means that the abundances of most chemical elements do not differ greatly from those that are measured by spectroscopic methods in the photosphere of the sun, which in turn should be well-representative of the entire solar system (note: to make such a comparison between a gaseous object like the sun and a rock like a chondrite, scientists choose one rock-forming element, such as silicon, to use as a reference point, and then compare ratios. Thus, the atomic ratio of Mg/Si measured in the sun (1.07) is identical to that measured in CI chondrites[29]).

Although all chondrite compositions can be considered primitive, there is variation among the different groups, as discussed above. CI chondrites seem to be nearly identical in composition to the sun for all but the gas-forming elements (e.g., hydrogen, carbon, nitrogen, and noble gases). Other chondrite groups deviate from the solar composition (i.e., they are fractionated) in highly systematic ways:

Petrologic types

A chondrite's group is determined by its primary chemical, mineralogical, and isotopic characteristics (above). The degree to which it has been affected by the secondary processes of thermal metamorphism and aqueous alteration on the parent asteroid is indicated by its petrologic type, which appears as a number following the group name (e.g., an LL5 chondrite belongs to the LL group and has a petrologic type of 5). The current scheme for describing petrologic types was devised by Van Schmus and Wood in 1967.[14]

The petrologic-type scheme originated by Van Schmus and Wood is really two separate schemes, one describing aqueous alteration (types 1–2) and one describing thermal metamorphism (types 3–6). The aqueous alteration part of the system works as follows:

The thermal metamorphism part of the scheme describes a continuous sequence of changes to mineralogy and texture that accompany increasing metamorphic temperatures. These chondrites show little evidence of the effects of aqueous alteration:

Some workers have extended the Van Schmus and Wood metamorphic scheme to include a type 7, although there is not consensus on whether this is necessary. Type 7 chondrites have experienced the highest temperatures possible, short of that required to produce melting. Should the onset of melting occur the meteorite would probably be classified as a primitive achondrite instead of a chondrite.

All groups of ordinary and enstatite chondrites, as well as R and CK chondrites, show the complete metamorphic range from type 3 to 6. CO chondrites comprise only type 3 members, although these span a range of petrologic types from 3.0 to 3.8.

Presence of water

These meteorites either contain a proportion of water or minerals that have been altered by water. This suggests that the asteroid from which these meteorites originate must have contained water. At the beginning of the Solar System this would have been present as ice and a few million years after the asteroid formed the ice would have melted allowing the liquid water to react with and alter the olivines and pyroxenes. The formation of rivers and lakes on the asteroid is thought to have been unlikely if it was sufficiently porous to allow the water to percolated towards its interior, as occurs in terrestrial aquifers.[30]

It is thought possible that the a proportion of the water present on the Earth comes from the impact of comets and carbonaceous chondrites with the Earth's surface.[31][32]

Origin of life

Amino acid general structure
The Murchison meteorite is on display at the Smithsonian’s NMNH.

Carbonaceous chondrites contain more than 600 organic compounds that were synthesized in distinct places and at distinct times. These organic compounds include: hydrocarbons, carboxylic acids, alcohols, ketones, aldehydes, amines, amides, sulfonic acids, phosphonic acids, amino acids, nitrogenous bases, etc.[33] These compounds can be divided into three main groups: a fraction that is not soluble in chloroform or methanol, chloroform soluble hydrocarbons and a fraction that is soluble in methanol (which includes the amino acids).

The first fraction appears to originate from interstellar space and the compounds belonging to the other fractions derive from a planetoid. It has been proposed that the amino acids were synthesized close to the surface of a planetoid by the radiolysis (dissociation of molecules caused by radiation) of hydrocarbons and ammonium carbonate in the presence of liquid water. In addition, the hydrocarbons could have formed deep within a planetoid by a process similar to the Fischer-Tropsch process. These conditions could be analogous to the events that caused the origin of life on Earth.[34]

The Murchison meteorite has been thoroughly studied, it fell in Australia close to the town that bears its name on 28 September 1969. It is a CM2 and it contains common amino acids such as glycine, alanine and glutamic acid as well as other less common ones such as isovaline and pseudo-leucine.[35]

Two meteorites that were collected in Antarctica in 1992 and 1995 were found to be abundant in amino acids, which are present at concentrations of 180 and 249 ppm (carbonaceous chondrites normally contain concentrations of 15 ppm or less). This could indicate that organic material is more abundant in the Solar System than was previously believed, and it reinforces the idea that the organic compounds present in the primordial soup could have had an extraterrestrial origin.[36]

See also

References

  1. "2.2 La composición de la Tierra: el modelo condrítico in Planetología. Universidad Complutense de Madrid". Retrieved 19 May 2012.
  2. The use of the term non-metallic does not imply the total absence of metals.
  3. 1 2 Calvin J. Hamilton (Translated from English by Antonio Bello). "Meteoroides y Meteoritos" (in Spanish). Retrieved 2009-04-18.
  4. Bischoff, A.; Geiger, T. (1995). "Meteorites for the Sahara: Find locations, shock classification, degree of weathering and pairing". Meteoritics. 30 (1): 113–122. Bibcode:1995Metic..30..113B. doi:10.1111/j.1945-5100.1995.tb01219.x. ISSN 0026-1114.
  5. Axxón. "Pistas químicas apuntan a un origen de polvo para los planetas terrestres" (in Spanish). Retrieved 11 May 2009.
  6. Jordi, Llorca Pique (2004). "Nuestra historia en los meteoritos". El sistema solar: Nuestro pequeño rincón en la vía láctea. Universitat Jaume I. p. 75. ISBN 848021466X.
  7. Amelin, Yuri; Krot, Alexander (2007). "Pb isotopic age of the Allende chondrules". Meteoritics & Planetary Science. 42 (7/8): 1043–1463. Bibcode:2007M&PS...42.1043F. doi:10.1111/j.1945-5100.2007.tb00559.x. Retrieved 2009-07-13.
  8. Wood, J.A. (1988). "Chondritic Meteorites and the Solar Nebula". Annual Review of Earth and Planetary Sciences. 16: 53–72. Bibcode:1988AREPS..16...53W. doi:10.1146/annurev.ea.16.050188.000413. 0084-6597, 53–72.
  9. "Bjurböle; Meteoritical Bulletin Database. The Meteoritical Society". Retrieved 6 March 2013.
  10. "Grassland; Meteoritical Bulletin Database. The Meteoritical Society". Retrieved 6 March 2013.
  11. 1 2 Múñoz-Espadas, M.J.; Martínez-Frías, J.; Lunar, R. (2003). "Mineralogía, texturas y cosmoquímica de cóndrulos RP y PO en la condrita Reliegos L5 (León, España)". Geogaceta (in Spanish). 34. 0213-683X, 35–38.
  12. Astrobiology Magazine. "¿Cocinó Júpiter a los meteoritos?" (in Spanish). Retrieved 18 April 2009.
  13. Boss, A.P.; Durisen, R.H. (2005). "Chondrule-forming Shock Fronts in the Solar Nebula: A Possible Unified Scenario for Planet and Chondrite Formation". The Astrophysical Journal. 621 (2): L137–L140. arXiv:astro-ph/0501592Freely accessible. Bibcode:2005ApJ...621L.137B. doi:10.1086/429160.
  14. 1 2 Van Schmus, W. R.; Wood, J. A. (1967). "A chemical-petrologic classification for the chondritic meteorites". Geochimica et Cosmochimica Acta. 31 (5): 747–765. Bibcode:1967GeCoA..31..747V. doi:10.1016/S0016-7037(67)80030-9.
  15. Clayton, R. N.; Mayeda, T. K. (1989), "Oxygen Isotope Classification of Carbonaceous Chondrites", Abstracts of the Lunar and Planetary Science Conference, 20: 169, Bibcode:1989LPI....20..169C
  16. Wlotzka, F. (Jul 1993), "A Weathering Scale for the Ordinary Chondrites", Meteoritics, 28: 460, Bibcode:1993Metic..28Q.460W
  17. Stöffler, Dieter; Keil, Klaus; Edward R.D, Scott (Dec 1991). "Shock metamorphism of ordinary chondrites". Geochimica et Cosmochimica Acta. 55 (12): 3845–3867. Bibcode:1991GeCoA..55.3845S. doi:10.1016/0016-7037(91)90078-J.
  18. 1 2 The Meteorite Market. "Types of Meteorites". Retrieved 2009-04-18.
  19. The E stands for Enstatite, H indicates a high metallic iron content of approximately 30%, and L low. The number refers to alteration.
  20. Except for the High Iron, all the other carbonaceous chondrites are named after a characteristic meteorite.
  21. 1 2 3 Norton, O.R. and Chitwood, L.A. Field Guide to Meteors and Meteorites, Springer-Verlag, London 2008
  22. New England Meteoritical Services. "Meteorlab". Retrieved 22 April 2009.
  23. http://meteorites.wustl.edu/id/metal.htm
  24. The Internet Encyclopedia of Science. "carbonaceous chondrite". Retrieved 26 April 2009.
  25. Aaron S. Burton; Jamie E. Elsila; Jason E. Hein; Daniel P. Glavin; Jason P. Dworkin (March 2013). Extra-terrestrial amino acids identified in metal-rich CH and CB carbonaceous chondrites from Antarctica. Meteoritics & Planetary Science. 48. pp. 390–402. doi:10.1111/maps.12063.
  26. Andrew M. Davis; Lawrence Grossman; R. Ganapathy (1977). "Yes, Kakangari is a unique chondrite". Nature. 265 (5591): 230–232. Bibcode:1977Natur.265..230D. doi:10.1038/265230a0. 0028-0836, 230–232.
  27. Michael K. Weisberga; Martin Prinza; Robert N. Claytonb; Toshiko K. Mayedab; Monica M. Gradyc; Ian Franchid; Colin T. Pillingerd; Gregory W. Kallemeyne (1996). "The K (Kakangari) chondrite grouplet". Geochimica et Cosmochimica Acta. 60 (21): 4253–4263. Bibcode:1996GeCoA..60.4253W. doi:10.1016/S0016-7037(96)00233-5. 0016-7037, 4253–4263.
  28. Meteorites.tv. Meteorites for Science, Education & Collectors. "R Group (Rumurutiites)". Retrieved 28 April 2009.
  29. Grevesse and Sauval (2005) in Encyclopedia of Astronomy & Astrophysics, IOP Publishing, Ltd.
  30. Meteorite Museum. University of New Mexico. Institute of Meteoritics. "Asteroid Geology: Water". Retrieved 28 April 2009.
  31. Drake, Michael J.; Righter, Kevin (2001). "Where did Earth's water come from?". GSA Annual Meeting. 109.
  32. Jörn Müller; Harald Lesch (2003). "Woher kommt das Wasser der Erde? – Urgaswolke oder Meteoriten.". Chemie in unserer Zeit (in German). 37 (4): 242–246. doi:10.1002/ciuz.200300282. ISSN 0009-2851.
  33. Jordi Llorca i Piqué (2004). "Moléculas orgánicas en el sistema solar: ¿dónde y cómo encontrarlas?". II Curso de Ciencias Planetarias de la Universidad de Salamanca (in Spanish).
  34. Hyman Hartman; Michael A. Sweeney; Michael A. Kropp; John S. Lewis (1993). "Carbonaceous chondrites and the origin of life". Origins of Life and Evolution of Biospheres. 23 (4). 0169-6149, 221–227.
  35. Kvenvolden, Keith A., Lawless, James; Pering, Katherine; Peterson, Etta; Flores, Jose; Ponnamperuma, Cyril, Kaplan, Isaac R.; Moore, Carleton (1970). "Evidence for extra-terrestrial amino-acids and hydrocarbons in the Murchison meteorite". Nature. 28 (5275): 923–926. Bibcode:1970Natur.228..923K. doi:10.1038/228923a0. PMID 5482102.
  36. Сarnegie Institution for Science (13 March 2008). "Meteorites a Rich Source for Primordial Soup". Retrieved 30 April 2009.
Wikimedia Commons has media related to Chondrites.
This article is issued from Wikipedia - version of the 11/8/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.