Tetrahedrite

Tetrahedrite is a copper antimony sulfosalt mineral with formula: (Cu,Fe)
12Sb
4S
13. It is the antimony endmember of the continuous solid solution series with arsenic-bearing tennantite. Pure endmembers of the series are seldom if ever seen in nature. Of the two, the antimony rich phase is more common. Other elements also substitute in the structure, most notably iron and zinc, along with less common silver, mercury and lead. Bismuth also substitutes for the antimony site and bismuthian tetrahedrite or annivite is a recognized variety. The related, silver dominant, mineral species freibergite, although rare, is notable in that it can contain up to 18% silver.

Tetrahedrite
Tetrahedrite, hübnerite and quartz from Mundo Nuevo Mine, Huamachuco, Sánchez Carrión, La Libertad, Peru (size: 61 x 57 mm, 110 g)
General
CategorySulfosalt mineral
Formula
(repeating unit)		(Cu,Fe)
12Sb
4S
13
Strunz classification2.GB.05
Crystal systemCubic
Crystal classHextetrahedral (43m)
H-M symbol: (4 3m)
Space groupI43m
Unit cella = 10.39(16) Å; Z = 2
Identification
ColorSteel gray to iron-gray
Crystal habitGroups of tetrahedral crystals; massive, coarse to fine compact granular
TwinningContact and penetration twins on {111}
CleavageNone
FractureUneven to subconchoidal
TenacitySomewhat brittle
Mohs scale hardness3 12 - 4
LusterMetallic, commonly splendent
StreakBlack, brown to dark red
DiaphaneityOpaque, except in very thin fragments
Specific gravity4.97
Optical propertiesIsotropic
Refractive indexn greater than 2.72
References[1][2]

Tetrahedrite gets its name from the distinctive tetrahedron shaped cubic crystals. The mineral usually occurs in massive form, it is a steel gray to black metallic mineral with Mohs hardness of 3.5 to 4 and specific gravity of 4.6 to 5.2.

It occurs in low to moderate temperature hydrothermal veins and in some contact metamorphic deposits. It is a minor ore of copper and associated metals. It was first described in 1845 for occurrences in Freiberg, Saxony, Germany.

Applications

California-based Alphabet Energy announced plans to offer a thermoelectric device based on tetrahedrite to turn heat into electricity. The company claimed that other thermoelectrics typically produce about 2.5 percent efficiency, while tetrahedrite could achieve 5 to 10 percent.[3]

Other thermoelectrics are either scarce, expensive ($24–146/kg vs $4 for tetrahedrite) and/or toxic. Working with a natural material also reduces manufacturing costs.[3]

Images
  • Tetrahedrite crystals with chalcopyrite and sphalerite from the Casapalca Mine, Peru (size: 8.2 x 6.4 x 4.7 cm)
  • Tetrahedrite from Casapalca Mine, Casapalca, Huarochiri Province, Lima Department, Peru
  • Rhodochrosite with fluorite, tetrahedrite and quartz; the tetrahedrite occurs as sharp, metallic crystals
  • Tetrahedrite crystals to several inches on size in combination with quartz crystals
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See also

References
  1. Handbook of Mineralogy
  2. "Tetrahedrite: Tetrahedrite mineral information and data". Mindat.org. 2014-07-12. Retrieved 2014-07-17.
  3. Jacobs, Suzanne (2014-07-12). "Cheaper Thermoelectric Materials | MIT Technology Review". Technologyreview.com. Retrieved 2014-07-17.

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