Kyanite

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Kyanite is a typically blue aluminosilicate mineral, found in aluminium-rich metamorphic pegmatites and sedimentary rock. It is the high pressure polymorph of andalusite and sillimanite, and the presence of kyanite in metamorphic rocks generally indicates metamorphism deep in the Earth's crust. Kyanite is also known as disthene or cyanite.<ref>Template:Cite book</ref>

Kyanite is strongly anisotropic, in that its hardness varies depending on its crystallographic direction. In kyanite, this anisotropism can be considered an identifying characteristic, along with its characteristic blue color. Its name comes from the same origin as that of the color cyan, being derived from the Ancient Greek word κύανος. This is typically rendered into English as kyanos or kuanos and means "dark blue."

Kyanite is used as a raw material in the manufacture of ceramics and abrasives, and it is an important index mineral used by geologists to trace metamorphic zones.

Kyanite is an aluminum silicate mineral, with the chemical formula Template:Chem2. It is typically patchy blue in color, though it can range from pale to deep blue<ref name=Sinkankas/> and can also be gray or white or, infrequently, light green.<ref name=Nesse2000>Template:Cite book</ref> It typically forms sprays of bladed crystals, but is less commonly found as distinct euhedral (well-shaped) crystals, which are particularly prized by collectors.<ref name=Sinkankas/> It has a perfect {100} cleavage plane, parallel to the long axis of the crystal, and a second good cleavage plane {010} that is at an angle of 79 degrees to the {100} cleavage plane. Kyanite also shows a parting on {001} at an angle of about 85 degrees to the long axis of the crystal.<ref name=Nesse2000/> Cleavage surfaces typically display a pearly luster. The crystals are slightly flexible.<ref name=Sinkankas>Template:Cite book</ref>

Kyanite's elongated, columnar crystals are usually a good first indication of the mineral, as well as its color (when the specimen is blue). Associated minerals are useful as well, especially the presence of the polymorphs of staurolite, which occurs frequently with kyanite. However, the most useful characteristic in identifying kyanite is its anisotropism. If one suspects a specimen to be kyanite, verifying that it has two distinctly different hardness values on perpendicular axes is a key to identification; it has a hardness of 5.5 parallel to {001} and 7 parallel to {100}.<ref name=Handbook/><ref name=Mindat/> Thus, a steel needle will easily scratch a kyanite crystal parallel to its long axis, but the crystal is impervious to being scratched by a steel needle perpendicular to the long axis.<ref name=Sinkankas/>

The kyanite structure can be visualized as a distorted face centered cubic lattice of oxygen ions, with aluminium ions occupying 40% of the octahedral sites and silicon occupying 10% of the tetrahedral sites. The aluminium octahedra form chains along the length of the crystal, half of which are straight and half of which are zigzag, with silica tetrahedra linking the chains together. There is no direct linkage between the silica tetrahedra, making kyanite a member of the nesosilicate class of silicate minerals.<ref>Template:Cite journal</ref>Template:Sfn

Template:Al2sio5 phase diagram Kyanite occurs in biotite gneiss, mica schist, and hornfels, which are metamorphic rocks formed at high pressure during regional metamorphism of a protolith which is rich in aluminium (a pelitic protolith). Kyanite is also occasionally found in granite and pegmatitesTemplate:Sfn<ref name=GeologyPage>Template:Cite web</ref> and associated quartz veins,<ref>Template:Cite book</ref> and is infrequently found in eclogites. It occurs as detrital grains in sedimentary rocks, although it tends to weather rapidly.<ref name=Nesse2000/><ref name=GeologyPage/> It is associated with staurolite, andalusite, sillimanite, talc, hornblende, gedrite, mullite and corundum.<ref name=Handbook/>

Kyanite is one of the most common minerals, having the composition Template:Chem2. Minerals with identical compositions but a different, distinct crystal structure are called polymorphs. There are two polymorphs of kyanite: andalusite and sillimanite. Kyanite is the most stable at high pressure, andalusite is the most stable at lower temperature and pressure, and sillimanite is the most stable at higher temperature and lower pressure.Template:Sfn They are all equally stable at the triple point near 4.2 kbar and Template:Convert.<ref>Template:Cite journal</ref> This makes the presence of kyanite in a metamorphic rock an indication of metamorphism at high pressure.

Kyanite is often used as an index mineral to define and trace a metamorphic zone that was subject to a particular degree of metamorphism at great depth in the crust. For example, G. M. Barrow defined kyanite zones and sillimanite zones in his pioneering work on the mineralogy of metamorphic rocks. Barrow was characterizing a region of Scotland that had experienced regional metamorphism at depth. By contrast, the metamorphic zones surrounding the Fanad pluton of Ireland, which formed by contact metamorphism at a shallower depth in the crust, include andalusite and sillimanite zones but no kyanite zone.<ref>Template:Cite book</ref>

Kyanite is potentially stable at low temperature and pressure. However, under these conditions, the reactions that produce kyanite, such as:

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never take place, and hydrous aluminosilicate minerals such as muscovite, pyrophyllite, or kaolinite are found instead of kyanite.Template:Sfn

Bladed crystals of kyanite are very common, but individual euhedral crystals are prized by collectors.<ref name=Sinkankas/> Kyanite occurs in Manhattan schist, formed under extreme pressure as a result of a continental collision during the assembly of the supercontinent of Pangaea.<ref>Template:Cite web</ref> It is also found in pegmatites of the Appalachian Mountains and in Minas Gerais, Brazil. Splendid specimens are found at Pizzo Forno in Switzerland.<ref name=Sinkankas/>

Kyanite can take on an orange color, which notably occurs in Loliondo, Tanzania.<ref name=":0" /> The orange color is due to inclusions of small amounts of manganese (Mn³⁺) in the structure.

Kyanite is used primarily in refractory and ceramic products, including porcelain plumbing and dishware. It is also used in electronics, electrical insulators and abrasives.Template:Sfn

At temperatures above 1100 °C, kyanite decomposes into mullite and vitreous silica via the following reaction:

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This transformation results in an expansion.<ref>Template:Cite book</ref> Mullitized kyanite is used to manufacture refractory materials.Template:Sfn

Kyanite has been used as a semiprecious gemstone, which may display cat's eye chatoyancy, though this effect is limited by its anisotropism and perfect cleavage. Color varieties include orange kyanite from Tanzania.<ref name=":0">Template:Cite journal</ref> The orange color is due to inclusions of small amounts of manganese (Mn³⁺) in the structure.<ref>Template:Cite journal</ref>

Specific citations

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General references

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