Kröhnkite Explained

Kröhnkite
Category:Sulfate mineral
Formula:Na2Cu(SO4)2•2H2O
Imasymbol:Khk[1]
Strunz:7.CC.30
Class:Prismatic (2/m)
(same H-M symbol)
Symmetry:P21/c
Unit Cell:a = 5.78 Å, b = 12.58 Å
c = 5.48 Å; β = 108.3°; Z = 2
Color:Blue, dark sky blue, greenish blue, yellowish green
Habit:Encrustations (on matrix), fibrous, massive
Twinning:Common, sometimes heart-shaped
Cleavage:Perfect, good (011), very imperfect
Fracture:Conchoidal
Mohs:2.5 – 3.0
Luster:Vitreous
Refractive:nα = 1.544 nβ = 1.578 nγ = 1.601
Opticalprop:Biaxial (-)
Birefringence:0.057
2V:78° measured
Streak:White
Gravity:2.92
Solubility:Readily soluble in water
Diaphaneity:Transparent
References:[2]

Kröhnkite (Na2Cu(SO4)2•2H2O) is a rare copper sulfate mineral named after B. Kröhnke who first researched it. Kröhnkite may be replaced by Saranchinaite, the anhydrous form of the mineral, if heated to temperatures above 200 °C (392 °F).

Crystallography

Kröhnkite has monoclinic symmetry (2/m).[3] Monoclinic symmetry implies that the mineral contains three axes of differing length (typically labeled a, b, and c), two of which intersect each other at 90° and one that intersects at an acute angle.[4] Specifically, it belongs to the 2/m symmetry class meaning, the mineral has a 2-fold rotation axis about the b axis.[4] It also has a unique motif of sulfate tetrahedra chains and copper octahedra aligned along the c axis and linked together by sodium atoms.[3] Kröhnkite exhibits the optical property birefringence; the difference in the two refractive indices of a mineral. Because this mineral is birefringent, it must be anisotropic. Anisotropic minerals cause the velocity of light to vary depending on the direction of travel through the mineral. Kröhnkite is biaxial negative, which reveals that the mineral has two optic axes.

Importance

Kröhnkite has the same general formula ((X2M(TO4)2(H2O)2)) as minerals which are found in environments affected by hydrothermal alteration, making it important in identifying where such alterations have occurred. Furthermore, the minerals sharing this composition are organized according to three crystal structure types, one being the unique kröhnkite structure which is often used to describe minerals exhibiting the same chain-like structure.[5]

Discovery and occurrence

Kröhnkite was first researched after an occurrence in the Chuquicamata Mine, Chile, and has been reported from a number of locations in the Atacama region. Associated minerals in the discovery location include atacamite, blodite, chalcanthite, antlerite and natrochalcite. It occurs in the oxidized zone of copper deposits in arid environments.[6]

Notes and References

  1. Warr. L.N.. 2021. IMA–CNMNC approved mineral symbols. Mineralogical Magazine. 85. 3. 291–320. 10.1180/mgm.2021.43. 2021MinM...85..291W. 235729616. free.
  2. "Kröhnkite Mineral Data." http://webmineral.com/data/Krohnkite.shtml. Accessed 28 November 2010.
  3. Hawthorne . F. C. . Ferguson . R. B. . Refinement of the crystal structure of kröhnkite . Acta Crystallographica Section B: Structural Crystallography and Crystal Chemistry . 15 June 1975 . 31 . 6 . 1753–1755 . 10.1107/S0567740875006048.
  4. Book: Schwarzenbach . Dieter . Crystallography . 1996 . John Wiley . New York . 978-0-471-95598-6.
  5. Herwig . S. . Hawthorne . F. C. . The topology of hydrogen bonding in brandtite, collinsite and fairfieldite . The Canadian Mineralogist . 1 October 2006 . 44 . 5 . 1181–1196 . 10.2113/gscanmin.44.5.1181.
  6. Web site: Anthony . John W. . Bideaux . Richard A. . Bladh . Kenneth W. . Nichols . Monte C. . Kröhnkite . Handbook of Mineralogy . Mineral Data Publishing . 22 May 2022 . 2005.