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Hübnerite

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Hubnerite
General
CategoryOxide minerals
Formula
(repeating unit)
MnWO4
IMA symbolHbr[1]
Strunz classification4.DB.30
Crystal systemMonoclinic
Crystal classPrismatic (2/m)
(same H-M symbol)
Space groupP21/c
Unit cella = 4.86, b = 5.78
c = 5.02 [Å]; β = 90.816°, Z = 4
Identification
ColorYellowish brown to reddish brown, blackish brown, black; Deep red internal reflections in reflected light
Crystal habitPrismatic striated crystals, tabular to flattened, in radiating groups
TwinningContact twins
CleavagePerfect on {010}
FractureIrregular/uneven
TenacityBrittle
Mohs scale hardness4–4+12
LusterMetallic to adamantine towards resinous.
StreakYellow to reddish brown, greenish gray
DiaphaneityTransparent to translucent
Specific gravity7.12–7.18
Optical propertiesBiaxial (+)
Refractive indexnα=2.17–2.2, nβ=2.22, nγ=2.3–2.32
Birefringence0.1200–0.1300
PleochroismPerceptible; X = yellow to green, red-orange; Y = yellowish brown to greenish yellow, red-orange to red; Z = green; brick-red to red
2V angle73° measured
References[2][3][4]

Hübnerite or hubnerite is a mineral consisting of manganese tungsten oxide (chemical formula MnWO4). It is the manganese endmember of the manganese–iron wolframite solid solution series. It forms reddish brown to black monoclinic prismatic submetallic crystals. The crystals are typically flattened and occur with fine striations. It has a high specific gravity of 7.15 and a Mohs hardness of 4.5. It is transparent to translucent with perfect cleavage. Refractive index values are nα = 2.170 – 2.200, nβ = 2.220, and nγ = 2.300 – 2.320.

Typical occurrence is in association with high-temperature hydrothermal vein deposits and altered granites with greisen, granite pegmatites and in alluvial deposits. It occurs associated with cassiterite, arsenopyrite, molybdenite, tourmaline, topaz, rhodochrosite and fluorite.[2]

It was first described in 1865 for an occurrence in the Erie and Enterprise veins, Mammoth district, Nye County, Nevada, and named after the German mining engineer and metallurgist, Adolf Hübner from Freiberg, Saxony.[2][4]

Introduction

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Hübnerite is a rare mineral from the rare family wolframite. It is considered to be one of the principle ores of tungsten. It is usually identified by the dark color, one direction of perfect cleavage and high specific gravity all serving to distinguish it from other minerals. The first recorded identification of the wolframite family was back in 1948 but it was not added as a mineral until 1951.[5]

Composition

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Since hübnerite comes from a family with only two end members it would be easier to explain the composition of the wolframite family since there is not enough data on hübnerite itself. The primary formula of the wolframite series is (Fe,Mn)WO4. The predominance of either iron or manganese results in formation of one of two minerals, the compositional end-members FeWO4 (ferberite) and MnWO4 (hübnerite), respectively.[6] Hübnerite is rarer than ferberite because of the difficulty of substituting manganese for iron. There are also other analogues, such as MgWO4.[7] These compounds are usually referred to as "wolframites" because they share the wolframite structure, but are not naturally occurring minerals, typically being produced for industrial applications, e.g., crystal scintillators.

Structure

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Sample from the Pasto Bueno District, Pallasca Province, Ancash Department, Peru, showing deep red internal reflections when backlit (Size: 6.6 x 4.2 x 1.6 cm)

Hübnerite is a rare end-member of the wolframite group, and has the same crystal structure as other members of the family. The crystal structure contains distorted tetrahedral (WO4) and octahedral ((Fe, Mn)O6) units. The wolframite family represents complete solid solution between Fe2+ and Mn2+.[5] In ferberite, the percentage of WO3 is around 76.3% whereas in hübnerite it is around 76.6%. In naturally occurring minerals the percent range falls within 20-80 percent. In the past it was thought that the wolframite structure possesses orthorhombic symmetry but in fact it possesses monoclinic symmetry. Short prismatic, flattened or wedge-shaped crystals are the common morphologies of wolframite crystals. In some rare cases the crystals occur doubly terminated. It is common for the faces to be striated parallel to the c axis.[7] In most cases, wolframite is found embedded in quartz as subparallel crystalline masses.

Physical properties

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Color differences between members of the wolframite family are clear and marked. The color of hübnerite varies from yellowish brown to reddish brown.[6] Crystal and crystalline masses of hübnerite show a variety of lusters from adamantine, submetallic to resinous luster.[8] In thin splints, hübnerite can be either transparent or translucent. The streak is related to the color being a shade lighter.[5] All the wolframite minerals exhibit perfect cleavage on {010}. On {100} and {102}, parting is less well-developed. Hübnerite exhibits brittle and uneven fracture. It is common for all members of the wolframite family to show simple contact twins on {100} or rarely interpenetrant twins on {001}. The hardness of hübnerite is between 4 and 4.5 and its specific gravity is between 7.12 and 7.18.

Geological occurrence

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Hübnerite is a rare member of the wolframite group. Hübnerite is usually found within pegmatites and high-temperature quartz veins. Hübnerite does not occur on its own,[7] but is typically associated with other minerals such as cassiterite, scheelite, quartz, galena, arsenopyrite, native bismuth, pyrite, and sphalerite.

History and uses

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Hübnerite was not the original name giving to the mineral. Hübnerite is a synonym of the original name, megabasite. The name megabasite was given to the mineral by A. Breithaupt in 1852. The name hübnerite was given to the mineral by E.N. Riotte in 1865 to honor the metallurgist Adolph Hübner.[5]

Hübnerite is primarily used as a source of tungsten. Tungsten is used to harden metal in the manufacture of high-speed tools.[8]

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. ^ a b c "Hübnerite Mn2+WO4" (PDF). Mineral Data Publishing. 2005.
  3. ^ Dave Barthelmy. "Hubnerite Mineral Data". webmineral.com.
  4. ^ a b "Hübnerite". mindat.org.
  5. ^ a b c d King, R. J. (2005). "Mineral Explained". Geology Today. 21 (1): 33–37. Bibcode:2005GeolT..21...33K. doi:10.1111/j.1365-2451.2005.00493.x. S2CID 140730723.
  6. ^ a b Errandonea, D.; Segura, A. (2010). "High-pressure phase transition and compressibility of wolframite-type tungstates". Journal of Applied Physics. 107 (8): 127–142. arXiv:0911.5609. Bibcode:2010JAP...107h3506R. doi:10.1063/1.3380848. S2CID 118457849.
  7. ^ a b c Neiva, A. M. R. (2008). "Geochemistry of cassiterite and wolframite from tin and tungsten quartz in Portugal". Ore Geology Reviews (33): 221–238. doi:10.1016/j.oregeorev.2006.05.013. hdl:10316/3927.
  8. ^ a b Dutrow, B.; Klein, C. (2007). "Tungstates and Molybdates". Mineral Science (21): 425–427.
  • Hu, W.B.; Nie, X.L.; Mi, Y.Zh. (2010). "Controlled synthesis and structure characterization of nanostructured MnWO4". Materials Characterization. 61 (6): 85–89. doi:10.1016/j.matchar.2009.10.009.