Like other
mica minerals, biotite has a highly perfect
basal cleavage, and consists of flexible sheets, or
lamellae, which easily flake off. It has a
monoclinic crystal system, with
tabular to
prismatic crystals with an obvious
pinacoid termination. It has four prism faces and two pinacoid faces to form a
pseudohexagonal crystal. Although not easily seen because of the cleavage and sheets, fracture is uneven. It appears greenish to brown or black, and even yellow when
weathered. It can be transparent to opaque, has a vitreous to pearly
luster, and a grey-white
streak. When biotite crystals are found in large chunks, they are called "books" because they resemble books with pages of many sheets. The color of biotite is usually black and the mineral has a hardness of 2.5–3 on the
Mohs scale of mineral hardness. Biotite
dissolves in both
acid and
alkaline aqueous solutions, with the highest
dissolution rates at low
pH. However, biotite dissolution is highly
anisotropic with crystal edge surfaces (
h k0) reacting 45 to 132 times faster than basal surfaces (
001). File:Biotite mica 2 (31739438210).jpg|Flaky biotite sheets. File:BiotitaEZ.jpg|Thick biotite sample featuring many sheets. File:Biotite1.jpg|Biotite crystal exhibiting pseudohexagonal shape.
Optical properties In
thin section, biotite exhibits moderate
relief and a pale to deep greenish brown or brown color, with moderate to strong
pleochroism. Biotite has a high
birefringence which can be partially masked by its deep intrinsic color. Under
cross-polarized light, biotite exhibits extinction approximately parallel to cleavage lines, and can have characteristic
bird's eye maple extinction, a mottled appearance caused by the distortion of the mineral's flexible lamellae during grinding of the thin section. Basal sections of biotite in thin section are typically approximately hexagonal in shape and usually appear
isotropic under cross-polarized light. File:Muscovite and Biotite2a.jpg|Biotite (in brown) and muscovite in an
orthogneiss thin section under plane-polarized light. File:Thin Section of Biotite (test) (cropped to Biotite).jpg|Biotite in thin section under cross-polarized light. File:Sagenitic biotite.JPG|Basal section of biotite, with needle-like
rutile inclusions, in thin section under plane-polarized light.
Structure Like other micas, biotite has a crystal structure described as
TOT-c, meaning that it is composed of parallel
TOT layers weakly bonded to each other by
cations (
c). The
TOT layers in turn consist of two tetrahedral sheets (
T) strongly bonded to the two faces of a single octahedral sheet (
O). It is the relatively weak ionic bonding between
TOT layers that gives biotite its perfect basal cleavage. The tetrahedral sheets consist of silica tetrahedra, which are silicon ions surrounded by four oxygen ions. In biotite, one in four silicon ions is replaced by an aluminium ion. The tetrahedra each share three of their four oxygen ions with neighboring tetrahedra to produce a hexagonal sheet. The remaining oxygen ion (the
apical oxygen ion) is available to bond with the octahedral sheet. The octahedral sheet in biotite is a trioctahedral sheet having the structure of a sheet of the mineral
brucite, with magnesium or ferrous iron being the usual cations. Apical oxygens take the place of some of the hydroxyl ions that would be present in a brucite sheet, bonding the tetrahedral sheets tightly to the octahedral sheet. Tetrahedral sheets have a strong negative charge, since their bulk composition is AlSi3O105-. The trioctahedral sheet has a positive charge, since its bulk composition is M3(OH)24+ (M represents a divalent ion such as ferrous iron or magnesium) The combined TOT layer has a residual negative charge, since its bulk composition is M3(AlSi3O10)(OH)2−. The remaining negative charge of the TOT layer is neutralized by the interlayer potassium ions. Because the hexagons in the T and O sheets are slightly different in size, the sheets are slightly distorted when they bond into a TOT layer. This breaks the hexagonal symmetry and reduces it to monoclinic symmetry. However, the original hexahedral symmetry is discernible in the pseudohexagonal character of biotite crystals. File:Mica T.png|View of tetrahedral sheet structure of biotite. The apical oxygen ions are tinted pink. File:Mica tO.png|View of trioctahedral sheet structure of biotite. The binding sites for apical oxygen are shown as white spheres. Red spheres are hydroxide ions. File:Mica tOs.png|View of trioctahedral sheet structure of mica emphasizing magnesium or iron sites File:Mica tri.png|View of biotite structure looking at surface of a single layer File:Mica tri side.png|View of biotite structure looking along sheets ==Occurrence==