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Moldavite

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Moldavite
Moldavite from Dobrkovská Lhotka
General
CategoryGlass
Formula
(repeating unit)
SiO2(+Al2O3)
Crystal systemAmorphous
Identification
ColorOlive green
Mohs scale hardness5.5[1] to 7[2]
LusterVitreous
DiaphaneityOpaque, translucent, transparent
Specific gravity2.32 to 2.38
Optical propertiesIsotropic
Refractive index1.48 to 1.54
BirefringenceNone
PleochroismAbsent
DispersionNone
References[1]

Moldavite (Czech: vltavín) is a forest green, olive green or blue greenish vitreous silica projectile glass formed by a meteorite impact in southern Germany (Nördlinger Ries Crater)[3] that occurred about 15 million years ago.[4] It is a type of tektite and a gemstone.[5] Material ejected from the impact crater includes moldavite, which was strewn across parts of Germany, the Czech Republic and Austria.[3]

Early studies

Moldavite was introduced to the scientific public for the first time in 1786 as "chrysolites" from Týn nad Vltavou in a lecture by Josef Mayer of Prague University, read at a meeting of the Bohemian Scientific Society (Mayer 1788). Zippe (1836) first used the term "moldavite", derived from the Vltava (Moldau) river in Bohemia (the Czech Republic), from where the first described pieces came.[6]

Origin

In 1900, Franz Eduard Suess pointed out that the gravel-size moldavites exhibited curious pittings and wrinkles on the surface, which could not be due to the action of water, but resembled the characteristic markings on many meteorites. He attributed the material to a cosmic origin and regarded moldavites as a special type of meteorite for which he proposed the name of tektite.[7] Based on an analysis of 23 Bohemian and Moravian samples, in 1966 it was theorised that variations in their composition derived from fractional volatilization, and were not similar in origin to sedimentary or igneous rocks. Values were reported for a range of attributes: oxides, and densities and refractive values index.[7] In 1987 it was recognised that moldavites were created following meteor impact which melted material and launched it into the air. As the material was airborne, it cooled and solidified. However, the plasma-like vapor at the impact site separated primary melt droplets from other residual vapour. The former then cooled into moldavite.[8] In 2019 the first LIBS (Laser Induced Breakdown Spectroscopy) study on two typical moldavite samples, followed by routine EPMA (Electron Probe Microanalysis), indicated agreement with EPMA studies and also revealed siderophile elements (Chromium, Iron, Cobalt and Nickel).[9]

Moldavites' highly textured surfaces are now known to be the result of pervasive etching by naturally occurring CO2 and humic acids present in groundwater.[10] Because of their extremely low water content and chemical composition, the current consensus among earth scientists is that moldavites were formed about 14.7 million years ago during the impact of a giant meteorite in the present-day Nördlinger Ries crater. Currently, moldavites have been found in an area that includes southern Bohemia, western Moravia, the Cheb Basin (northwest Bohemia), Lusatia (Germany), and Waldviertel (Austria).[11] Isotope analysis of samples of moldavites have shown a beryllium-10 isotope composition similar to the composition of Australasian tektites (australites) and Ivory Coast tektites (ivorites).[12]

Most moldavites are from South Bohemian localities, with just a few found in South Moravian localities. Rare moldavites have been found in the Lusatian area (near Dresden), Cheb basin area (West Bohemia) and Northern Austria (near Radessen). Principal occurrences of moldavites in Bohemia are associated with Tertiary sediments of the České Budějovice and Třeboň basins. The most prominent localities are concentrated in a NW-SE strip along the western margin of the České Budějovice Basin. The majority of these occurrences are bound to the Vrábče Member and Koroseky Sandy Gravel. Prominent localities in the Třeboň Basin are bound to gravels and sands of the Domanín Formation.

In Moravia, moldavite occurrences are restricted to an area roughly bounded by the towns of Třebíč, Znojmo and Brno. The colour of Moravian moldavites usually differs from their Bohemian counterparts, as it tends to be brownish. Taking into account the number of pieces found, Moravian localities are considerably less productive than the Bohemian ones; however, the average weight of the moldavites found is much higher. The oldest (primary) moldavite-bearing sediments lie between Slavice and Třebíč. The majority of other localities in southern Moravia are associated with sediments of Miocene as well as Pleistocene rivers that flowed across this area more or less to the southeast, similar to the present streams of Jihlava, Oslava and Jevišovka.

Properties

The chemical formula of moldavite is SiO2(+Al2O3). Its properties are similar to those of other types of glass, and reported Mohs hardness varies from 5.5[1] to 7.[2] Moldavite can be transparent or translucent with a mossy green color, with swirls and bubbles accentuating its mossy appearance. Moldavites can be distinguished from most green glass imitations by observing their worm-like schlieren.

Use

Moldavites were discovered by prehistoric people in the Czech Republic and Austria and were used to make flaked tools. Some of the worked moldavites date to the Aurignacian period of the Upper Paleolithic, approximately 43,000 to 26,000 years before the present.[13]

In the modern world, moldavites are often used, rough or cut, as semi-precious stones in jewelry. They have purported metaphysical qualities and are often used in crystal healing.

Presentation

There is the Moldavite Museum in Český Krumlov, Czech Republic.[14]

References

  1. ^ a b c "Moldavite". Gemdat.org. Retrieved 6 February 2016.
  2. ^ a b O'Keefe A., John. "Tektites and their Origin"., Goddard Space Centre, NASA. Retrieved 9 December 2017.
  3. ^ a b Artemieva, N., Pierazzo, E., Stöffler, D. (2002). "Numerical modeling of tektite origin in oblique impacts: Implication to Ries-Moldavites strewn field" (PDF). Bulletin of the Czech Geological Survey. 77. Czech Geological Survey: 303–311.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  4. ^ Earth Impact Database: Ries Archived 2016-03-04 at the Wayback Machine at www.passc.net/EarthImpactDatabase, Accessed 5 February 2018
  5. ^ Paisarnsombat, S.; Monarumit, N.; Aimploysri, S. (2021). "Characteristic of Fe in tektite observed from XANES and UV-Vis spectroscopy". Journal of Physics: Conference Series. 1719 (1): 012002. Bibcode:2021JPhCS1719a2002P. doi:10.1088/1742-6596/1719/1/012002. S2CID 234231433.
  6. ^ "Moldavite" at Mindat.org, Accessed 5 February 2018
  7. ^ a b J.A Philpotts; W.H Pinson New data on the chemical composition and origin of moldavites. Geochimica et Cosmochimica Acta,Volume 30, Issue 3 (1966) Pages 253-266
  8. ^ W.V Engelhardt; E Luft; J Arndt; H Schock; W Weiskirchner Origin of moldavites. Geochimica et Cosmochimica Acta,Volume 51, Issue 6 (1987) Pages 1425-1443
  9. ^ Abhishek K. Rai; Jayanta K. Pati; Rohit Kumar Spectro-chemical study of moldavites from Ries impact structure (Germany) using LIBS Optics & Laser Technology, Volume 114 (2019) Pages 146-157
  10. ^ Skála, R.; Strnad, L.; McCammon, C.; Čada, M. (2009). "Moldavites from the Cheb Basin, Czech Republic". Geochimica et Cosmochimica Acta. 73 (4): 1149–1179. Bibcode:2009GeCoA..73.1145S. doi:10.1016/j.gca.2008.11.003.
  11. ^ Trnka, M.; Houzar, S. (2002). "Moldavites: a review PDF" (PDF). Bulletin of the Czech Geological Survey. 77 (4): 283–302.
  12. ^ Serefiddin, F.; Herzog, G. F.; Koeberl, C. (2007). "Beryllium-10 concentrations of tektites from the Ivory Coast and from Central Europe: Evidence for near-surface residence of precursor materials" (PDF). Geochimica et Cosmochimica Acta. 71 (6): 1574–1582. Bibcode:2007GeCoA..71.1574S. doi:10.1016/j.gca.2006.12.007.
  13. ^ Williams, Olwen; Nandris, John (1977). "The Hungarian and Slovak sources of archaeological obsidian: an interim report on further fieldwork, with a note on tektites". Journal of Archaeological Science. 4 (3): 207–219. Bibcode:1977JArSc...4..207W. doi:10.1016/0305-4403(77)90089-9.
  14. ^ "Home". Moldavite Museum. Retrieved 2022-07-08.

 This article incorporates text from a publication now in the public domainChisholm, Hugh, ed. (1911). "Moldavite". Encyclopædia Britannica. Vol. 18 (11th ed.). Cambridge University Press. p. 652.

Further reading

  • Milan PRCHAL "60 years on the green wave". (Robert Jelinek, Admir Mesic Eds). Der Konterfei 072, Vienna, 2021. ISBN 978-3-903043-59-6
  • The Austrian Moldavite – On the Traces of the Green Tektite (Robert Jelinek Ed.). Der Konterfei 078, Vienna, 2023. ISBN 978-3-903043-66-4