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Bentorite

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Bentorite
Bentorite found in Israel
General
CategoryMineral
Formula
(repeating unit)
Ca6(Cr,Al)2(SO4)3(OH)12· 26H2O
IMA symbolBto[1]
Strunz classification7.DG.15 (9th Ed)
Dana classification31.10.2.2
Unit cell2,355.60 ų
Identification
ColourViolet to rose-purple
Twinning(1010)
CleavagePerfect
FractureSub-conchoidal
Mohs scale hardness2
LusterResinous, waxy, earthy
StreakVery pale purple
Specific gravity2.025
Density2.025 g/cm3 (measured)
Birefringence0.006
PleochroismVisible
ExtinctionParallel
Ultraviolet fluorescenceNot fluorescent
Absorption spectraE > O

Bentorite is a mineral with the chemical formula Ca6(Cr,Al)2(SO4)3(OH)12·26H2O. It is colored violet to light violet. Its crystals are hexagonal to dihexagonal dipyramidal. It is transparent and has vitreous luster. It has perfect cleavage. It is not radioactive. Bentorite is rated 2 on the Mohs scale.

The mineral was first described in 1980 by Shulamit Gross for an occurrence in the Hatrurim Formation of Danian age along the western margin of the Dead Sea, Israel. It was named by its discoverer, Shulamit Gross, for Yaakov Ben-Tor (1910–2002), Professor at the Hebrew University of Jerusalem and the University of California, San Diego, California, US, for his contributions to geology and mineralogy in Israel.[2][3]

Formation

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The only naturally occurring bentorite that has been discovered is in the Hatrurim Formation near the Dead Sea in Israel. The formation consists of a mixture of metamorphosed clays, limestones, and marls. The original sediments were enriched in chromium, and later experienced heating to >1000 °C at atmospheric pressure. This formed a natural Portland cement which has since been hydrated from groundwater and/or rainwater to form a natural concrete. The source of the heat is thought to be due to combustion of coal, oil, or gas. Following this combustion metamorphosis, highly alkaline fluids penetrated and altered the rock to form supergene veins of bentorite.[4]

Applications

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When suitably prepared, concrete contains crystals of ettringite that can exchange aluminium for chromium, converting the ettringite to bentorite. This allows concretes to sequester chromium present as an environmental pollutant.[5]

See also

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References

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  1. ^ Warr, L.N. (2021). "IMA–CNMNC approved mineral symbols". Mineralogical Magazine. 85 (3): 291–320. Bibcode:2021MinM...85..291W. doi:10.1180/mgm.2021.43. S2CID 235729616.
  2. ^ Handbook of Mineralogy
  3. ^ - Webmineral data
  4. ^ Seryotkin, Yurii V.; Sokol, Ella V.; Kokh, Svetlana N.; Murashko, Mikhail N. (March 2018). "Natural Cr3+-rich ettringite: occurrence, properties, and crystal structure". Physics and Chemistry of Minerals. 45 (3): 279–292. doi:10.1007/s00269-017-0917-y. S2CID 102591244.
  5. ^ Yang, Fengming; Zhou, Xin; Pang, Fangjie; Wang, Weijie; Wang, Wenlong; Wang, Zengmei (October 2021). "Heavy metal removal of solid waste source sulphoaluminate cement with graphene oxide". Construction and Building Materials. 303: 124460. doi:10.1016/j.conbuildmat.2021.124460.