Pallasite Explained

The pallasites are a class of stony–iron meteorite. They are relatively rare, and can be distinguished by the presence of large olivine crystal inclusions in the ferro-nickel matrix.

These crystals represent mantle and core material from differentiated planetesimals, which were destroyed by violent collisions during the early formation of the Solar System.

Structure and composition

It consists of centimetre-sized olivine crystals of peridot quality in an iron-nickel matrix. Coarser metal areas develop Widmanstätten patterns upon etching. Minor constituents are schreibersite, troilite, chromite, pyroxenes, and phosphates (whitlockite, stanfieldite, farringtonite, and merrillite).^{[1] [2]}

Classification and subgroups

Using the oxygen isotopic composition, meteoric iron composition and silicate composition pallasites are divided into 4 subgroups:^{[3] [4]}

• Main group pallasites (PMG): Almost all pallasites
• Eagle Station group (PES): 5 specimens known. They are related to IIF irons.
• Pyroxene Pallasite grouplet (PPX): Counts only Vermillion and Yamato 8451. They take their name from the high orthopyroxene content (about 5%). Metal matrix shows a fine octahedrite Widmanstätten pattern.
• Pallasite ungrouped (P-ung): Specimens that don't fit into any groups or grouplets

Origin

Pallasites were once thought to originate at the core-mantle boundary of differentiated asteroids that were subsequently shattered through impacts. An alternative recent hypothesis is that they are impact-generated mixtures of core and mantle materials. This hypothesis is supported by isotopic analysis indicating admixture of material from multiple planetesimals.^{[5] [6]}

History

A common error is to associate their name with the asteroid 2 Pallas but their actual name is after the German naturalist Peter Pallas (1741–1811), who studied in 1772 a specimen found earlier near Krasnoyarsk in the mountains of Siberia that had a mass of . The Krasnoyarsk mass described by Pallas in 1776 was one of the examples used by E.F.F. Chladni in the 1790s to demonstrate the reality of meteorite falls on the Earth, which most scientists at his time considered as fairytales. This rock mass was dissimilar to all rocks or ores found in this area (and the large piece could not have been accidentally transported to the find site), but its content of native metal was similar to other finds known from completely different areas.^{[7] [8]}

Pallasite falls

Pallasites are a rare type of meteorite. Only 61 are known to date, including 10 from Antarctica, with four being observed falls.^{[9] [10]} The following four falls are in chronological order:

• Mineo, Sicily, Italy. A luminous meteor was observed and an object seen to fall with a loud roar in May 1826. Only are preserved in collections.
• Zaisho, Japan. 330 g were found on February 1, 1898,^[11] after the appearance of a fireball.
• Marjalahti, Karelia, Russia. After the appearance of a bright meteor and detonations, a large mass was seen to fall and were recovered in June 1902. At this date the fall site belonged to Finland, and the main mass of Marjalahti is now at the Geological Museum of the University of Helsinki.
• Omolon, Magadan Region, Russia. A reindeer-breeder observed the fall on May 16, 1981, and found the meteorite two years later. The fall was confirmed by a meteorological station that had observed a fireball on the same date.

Notable pallasite finds

Although pallasites are a rare meteorite type, enough pallasite material is found in museums and meteorite collections and is available for research. This is due to several large finds, some of which yielded more than a metric ton. The following are the largest finds:

• Brenham, Kansas, United States. In 1890 the find of about 20 masses with a total weight of around the shallow Haviland Crater were reported. More masses were found later, including one of from a depth of, the total amounting to about . A piece of is in the Field Museum of Natural History, Chicago. In 2005, Steve Arnold of Arkansas, USA, and Phil Mani of Texas, USA, unearthed a large mass of and in 2006 several new large masses ^{[12] [13]} Don Stimpson and Sheila Knepper have found approximately 8,000 lbs. of the Brenham meteorite on their farm property.^[14]
• Huckitta, Northern Territory, Australia. A mass of was found in 1937 on a cattle station north-east of Alice Springs. Earlier, in 1924, a transported piece of about had been found on Burt Plain north of Alice Springs.
• Fukang, Xinjiang Province, China. A mass of was recovered in 2000.
• Imilac, Atacama Desert, Chile; known since 1822. Numerous masses up to were found, the total weight is about 920 kg.
• Brahin, Gomel Region, Belarus, known since 1810. Many masses were found strewn in a field, with a total weight of about 820 kg. An additional mass of 227 kg was found at a depth of in 2002.
• Esquel, Chubut, Argentina. A large mass of 755 kg was found embedded in soil before 1951.
• Pallasovka, Pallasovka, Russia. A single mass of 198 kg was found near Pallasovka, Russia in 1990. Coincidentally, both the town of Pallasovka and pallasite meteorites were named after the naturalist, Peter Pallas.
• Krasnojarsk, Yeniseisk, Russia. A mass of about 700 kg was detected in 1749 about south of Krasnojarsk.^[15] It was seen by P. S. Pallas in 1772 and transported to Krasnojarsk (see above). The main mass of 515 kg is now in Moscow at the Academy of Sciences. Pallasites are named after Peter Pallas for his study of this meteorite.
• Seymchan, discovered near the town by the same name, in far eastern Russia in 1967. This main group Pallasite has some areas free of olivine crystals, and may have formed near the junction of the core and the mantle of an asteroid. Multiple masses in excess of 1 tonne have been recovered.

See also

• Glossary of meteoritics
• Port Orford meteorite hoax

External links

• Pallasite images from Meteorites Australia - Meteorites.com.au
• Legend of Glorieta Mountain Discovery of a large pallasite in New Mexico

Notes and References

1. Buseck . P.R. . 1977 . Pallasite meteorites: mineralogy, petrology, and geochemistry . Geochimica et Cosmochimica Acta . 41 . 711–740 . 10.1016/0016-7037(77)90044-8. 1977GeCoA..41..711B . 6 .
2. Hsu . W. . 2003 . Minor element zoning and trace element geochemistry of pallasites . Meteoritics & Planetary Science . 38 . 8 . 1217–1241 . 10.1111/j.1945-5100.2003.tb00309.x. 2003M&PS...38.1217H . 73597247 . free .
3. O. Richard Norton. The Cambridge encyclopedia of meteorites. Cambridge, Cambridge University Press, 2002. .
4. Book: D. S. Lauretta . H. Y. McSween, Jr.. Meteorites and the early solar system II. 2006. University of Arizona Press. Tucson. 978-0816525621. M. K. Weisberg. T. J. McCoy, A. N. Krot. 15 December 2012. 19–52. Systematics and Evaluation of Meteorite Classification.
5. Edward R.D. Scott, "Impact Origins for Pallasites," Lunar and Planetary Science XXXVIII, 2007.
6. Windmill . Richard J. . March 2022 . Isotopic evidence for pallasite formation by impact mixing of olivine and metal during the first 10 million years of the Solar System . PNAS Nexus . 1 . 1 . pgac015 . 10.1093/pnasnexus/pgac015. 36712802 . 9802258 .
7. Chladni. Observation on a mass of iron found in Siberia by Professor Pallas, and other masses of the like kind, with some conjectures respecting their connection with certain natural phenomena. The Philosophical Magazine. 1798. 2. 5. 1–8. 10.1080/14786449808676869.
8. Book: Chladni. Ernst Florens Friedrich. Über den Ursprung der von Pallas gefundenen und anderer ihr ähnlicher Eisenmassen und über einige damit in Verbindung stehende Naturerscheinungen. On the origin of the iron masses found by Pallas and others similar to it, and on some natural phenomena associated with them. 1794. Johann Friedrich Hartknoch. Riga, Latvia. 9783111274386. de.
9. http://www.lpi.usra.edu/meteor Meteoritical Bulletin Database
10. http://www.Metbase.de MetBase
11. Web site: Meteorites Japan . 2009-04-13 . https://web.archive.org/web/20080506094612/http://meteoritesjapan.com/japmets.aspx . 2008-05-06 . dead .
12. http://www.agiweb.org/geotimes/jan06/NN_Brenhammeteor.html Mammoth meteorite unearthed
13. http://www.cnn.com/2006/TECH/space/10/16/meteorite.kansas.ap/index.html?section=cnn_space CNN: Unusual meteorite found in Kansas
14. Web site: Haviland, Kansas: Kansas Meteorite Museum . RoadsideAmerica.com . April 20, 2022.
15. The original location of the Krasnojarsk meteorite was: 54° 54' N, 91° 48' E. See:
    • The Meteoritical Society
    • Pallas. Peter S.. Account of the iron ore lately found in Siberia. Philosophical Transactions of the Royal Society of London. 1776. 66. 523–529. 10.1098/rstl.1776.0035. free. Pallas describes the location of the meteorite (which he calls a "mass of native iron") on p. 525.