Microcline

Microcline
Microcline
General
Category	Tektosilicate
Formula; (repeating unit)	KAlSi3O8
Space group	P1 (no. 2)
Identification
Color	White, grey, greyish yellow, yellowish, tan, salmon-pink, bluish green, green.
Crystal habit	Can be anhedral or euhedral. Grains are commonly elongate with a tabular appearance. May contain lamellae which formed from exsolved albite.
Twinning	Typically displays and pericline twinning. This combination leads to a grid pattern, hence microcline displays . Can also display , simple twins, or lack twinning altogether. Lamellae in microcline are discontinuous and "pinch and swell." Photomicrograph of thin section of microcline showing crosshatched crystal twinning (in cross polarized light)
Cleavage	Has perfect cleavage parallel to {001} and good cleavage on {010}. Cleavages intersect at 90°41'. It can be difficult to see cleavage in thin section due to microcline's low relief.
Tenacity	Brittle
Mohs scale hardness	6-6.5
Luster	Vitreous
Streak	White
Diaphaneity	Transparent, translucent
Specific gravity	2.5-2.6
Optical properties	Biaxial negative
Refractive index	nα = 1.514 - 1.529 nβ = 1.518 - 1.533 nγ = 1.521 - 1.539
Birefringence	Up to first order white (roughly 0.007)
Pleochroism	N/A
2V angle	65–88°
Extinction	Inclined extinction to cleavage
Diagnostic features	Gridiron twinning distinguishes microcline from other feldspars. Distinguishable from plagioclase because the lamellae in plagioclase are continuous and do not "pinch and swell."
Alters to	Commonly alters to sericite or clay.
Relief	Low negative relief
Optical sign	Biaxial negative
Color in PPL	Colorless

Microcline (KAlSi₃O₈) is an important igneous rock-forming tectosilicate mineral. It is a potassium-rich alkali feldspar. Microcline typically contains minor amounts of sodium. It is common in granite and pegmatites. Microcline forms during slow cooling of orthoclase; it is more stable at lower temperatures than orthoclase. Sanidine is a polymorph of alkali feldspar stable at yet higher temperature. Microcline may be clear, white, pale-yellow, brick-red, or green; it is generally characterized by cross-hatch twinning that forms as a result of the transformation of monoclinic orthoclase into triclinic microcline.

The chemical compound name is potassium aluminium silicate, and it is known as E number reference E555.

Geology[]

Microcline may be chemically the same as monoclinic orthoclase, but because it belongs to the triclinic crystal system, the prism angle is slightly less than right angles; hence the name "microcline" from the Greek "small slope." It is a fully ordered triclinic modification of potassium feldspar and is dimorphous with orthoclase. Microcline is identical to orthoclase in many physical properties, and can be distinguished by x-ray or optical examination. When viewed under a polarizing microscope, microcline exhibits a minute multiple twinning which forms a grating-like structure that is unmistakable.

Feldspar (Amazonite)

Perthite is either microcline or orthoclase with thin lamellae of exsolved albite.

Amazon stone, or amazonite, is a green variety of microcline. It is not found anywhere in the Amazon Basin, however. The Spanish explorers who named it apparently confused it with another green mineral from that region.

The largest documented single crystals of microcline were found in Devils Hole Beryl Mine, Colorado, US and measured ~50x36x14 m. This could be one of the largest crystals of any material found so far.^[1]

Microcline is commonly used for the manufacturing of porcelain.

As food additive[]

The chemical compound name is potassium aluminium silicate, and it is known as E number reference E555. It was the subject in 2018 of a Call for technical and toxicological data from the EFSA.^[2]

In 2008, it (along with other Aluminum compounds) was the subject of a Scientific Opinion of the Panel on Food Additives, Flavourings, Processing Aids and Food Contact Materials from the EFSA.^[3]

References[]

^ P. C. Rickwood (1981). "The largest crystals" (PDF). American Mineralogist. 66: 885–907.
^ "Call for technical and toxicological data on sodium aluminium silicate (E 554) and potassium aluminium silicate (E 555) authorised as food additives in the EU". EFSA.
^ F. Aguilar, H. Autrup, S. Barlow, L. Castle, R. Crebelli, W. Dekant, K.-H. Engel, N. Gontard, D. Gott, S. Grilli, R. Gürtler, J.-C. Larsen, C. Leclercq, J.-C. Leblanc, F.-X. Malcata, W. Mennes, M.-R. Milana, I. Pratt, I. Rietjens, P. Tobback, F. Toldrá. (2008). "Safety of aluminium from dietary intake[1] - Scientific Opinion of the Panel on Food Additives, Flavourings, Processing Aids and Food Contact Materials (AFC)". EFSA Journal. 6 (7). doi:10.2903/j.efsa.2008.754.CS1 maint: multiple names: authors list (link)

[1] P. C. Rickwood (1981). "The largest crystals" (PDF). American Mineralogist. 66: 885–907.

[2] "Call for technical and toxicological data on sodium aluminium silicate (E 554) and potassium aluminium silicate (E 555) authorised as food additives in the EU". EFSA.

[3] F. Aguilar, H. Autrup, S. Barlow, L. Castle, R. Crebelli, W. Dekant, K.-H. Engel, N. Gontard, D. Gott, S. Grilli, R. Gürtler, J.-C. Larsen, C. Leclercq, J.-C. Leblanc, F.-X. Malcata, W. Mennes, M.-R. Milana, I. Pratt, I. Rietjens, P. Tobback, F. Toldrá. (2008). "Safety of aluminium from dietary intake[1] - Scientific Opinion of the Panel on Food Additives, Flavourings, Processing Aids and Food Contact Materials (AFC)". EFSA Journal. 6 (7). doi:10.2903/j.efsa.2008.754.CS1 maint: multiple names: authors list (link)

[1]

[2]

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Microcline

Contents

Geology[]

As food additive[]

See also[]

References[]