Presentation is loading. Please wait.

Presentation is loading. Please wait.

The name of biotite comes from the French physicist J. B. Biot

Published byMelissa Wilkins Modified over 9 years ago

Similar presentations

Presentation on theme: "The name of biotite comes from the French physicist J. B. Biot"— Presentation transcript:

1 The name of biotite comes from the French physicist J. B. Biot
Trioctahedral micas By Dominic Papineau Annite (Potassium Iron Aluminum Silicate Hydroxide) Aspidolite (Sodium Magnesium Aluminum Silicate Hydroxide) Biotite (Potassium Magnesium Iron Aluminum Silicate Hydroxide Fluoride) Eastonite (Potassium Magnesium Aluminum Silicate Hydroxide) Ephesite (Sodium Lithium Aluminum Silicate Hydroxide) Hendricksite (Potassium Zinc Aluminum Silicate Hydroxide) Lepidolite (Potassium Lithium Aluminum Silicate Fluoride Hydroxide) Masutomilite (Potassium Lithium Aluminum Manganese Silicate Fluoride) Montdorite (Potassium Iron Manganese Magnesium Aluminum Silicate Fluoride) Norrishite (Potassium Lithium Manganese Silicate) Polylithionite (Potassium Lithium Aluminum Silicate Fluoride) Phlogopite (Potassium Magnesium Aluminum Silicate Hydroxide) Preiswerkite (Sodium Magnesium Aluminum Silicate Hydroxide) Siderophyllite (Potassium Iron Aluminum Silicate Hydroxide) Tainiolite (Potassium Lithium Magnesium Silicate Fluoride) Tetra-ferri-annite (Potassium Iron Silicate Hydroxide) Tetra-ferriphlogopite (Potassium Magnesium Iron Silicate Hydroxide) Trilithionite (Potassium Lithium Aluminum Silicate Fluoride) Zinnwaldite (Potassium Lithium Iron Aluminum Silicate Fluoride Hydroxide) The name of biotite comes from the French physicist J. B. Biot

2 The chemical and structural properties of biotite
Chemical formula of biotite: K(Mg,Fe)3(AlSi3O10)(OH)2 The composition is similar to phlogopite but with considerable substitution of Fe2+ for Mg. In fact, biotite is an intermediate between phlogopite and annite. A complete solid solution exists between annite, biotite, and phlogopite. Other common substitutions include Ti, Fe3+ and Al for Mg in the octahedral site and also Al for Si in the tetrahedral site. Substitution of F and Cl for OH are also common. Substitutions can also occur in the site of the interlayer cation K+ where Na, Ca, NH4+, Ba, Rb, and Cs can substitute. Biotite is more susceptible to chemical weathering than muscovite, because the Fe2+ can oxidize to Fe3+ in the presence of an electron acceptor. As a result, the mineral alters to other aluminosilicates and ferric oxide.

3 The physical properties of biotite
Colors: brown (high Fe + Mg and low Ti), green-brown (low Ti), blue-green (no Ti), or black. Luster: splendent Cleavage: perfect in one direction Hardness: 2.5 to 3 Density: 2.8 to 3.2 g/cm3 Crystal habit: generally tabular crystals with a pseudohexagonal shape.

4 The optical properties of biotite
Biotite is biaxial negative 2VZ = 0o - 25°  = 1.57 – 1.63  = 1.61 – 1.70 = 1.61 – 1.70 = to (third order interference colors seen as a “bird’s eye texture”) Strongly pleochroic 0o to 9o extinction angle

5 The crystallographic properties of biotite
Crystal system: monoclinic Point Group: 2/m Unit cell parameters: a = 5.31 b = 9.23 c = 10.18  = 99.3° Z = 2 V = Calculated density = 2.89 Space group: C2/m is the most common (1M)

6 The crystal structure of biotite
Silicon or aluminum tetrahedra Iron or magnesium octahedron Oxygen atom Potassium or interlayer cation The tetrahedral sheets are 2.271Å thick for 1M biotite The octahedral sheets are 2.138Å thick for 1M biotite The interlayer separation is of 3.334Å for 1M biotite

7 Optical spectroscopic properties of biotite
Fe2+ is observed by absorption bands near: 270 nm ( cm-1) 385 nm ( cm-1) Near UV, Visible, and Near IR 456 nm ( cm-1) 720 nm ( cm-1) 920 nm ( cm-1) 1150 nm (9 000 cm-1) Cr3+ is observed by absorption bands near: 400 nm ( cm-1) Visible 600 nm ( cm-1) Ti3+ is observed by absorption bands near: 400 to 500 nm ( to cm-1) Visible

8 Infrared spectroscopic properties of biotite
Infrared spectroscopy in micas can be used for: Mica and polytype identification Estimation of chemical composition Determine ordering and orientation of small molecular units Derive thermodynamic parameters Examine the interaction of a wide variety of chemical substances with micas OH-stretching is observed by absorption bands near: 930 nm ( cm-1) 1380 nm (7250 cm-1) Wavenumber (cm-1) 2700 nm (3710 cm-1) Phlogopite 2760 and 2900 nm (3620 and 3450 cm-1)

9 The crystallization of biotite in igneous rocks

10 The crystallization of biotite from sediments
Biotite can crystallize from pelitic sediments (metamorphosed argillaceous sediments). This metamorphism occurs by a series of dehydration reactions The most basic requirements to obtain some biotite in metamorphic rocks are a little K2O, sufficient Al2O3 and the appropriate metamorphic conditions. Biotite in pelitic schist thus originates from mineral reactions which include quartz, muscovite, biotite, chlorite, and K-feldspar. Biotite Ti content increases as a function of metamorphic grade

11 The stability of biotite in metamorphic processes
Biotite is stable from greenschist to granulite facies

12 Occurrences of biotite
Biotite occurs in a wide variety of environments Igneous rocks: Granite, gabbro, diorite, peridotite, monzonite, syenite, etc. Pegmatites: Where it can contain some rare-earth elements. Metamorphic rocks: Found in a wide range of temperature and pressure conditions characterizing the biotite zone.

Download ppt "The name of biotite comes from the French physicist J. B. Biot"

Similar presentations

Inosilicates (chain) Common Fe/Mg – bearing silicates

Inosilicates (chain) Common Fe/Mg – bearing silicates
Disilicates and Ring Silicates

Disilicates and Ring Silicates
AMPHIBOLES (double chains)  General formula:  X 2 Y 5 Z 8 O 22 (OH) 2 the box is a site that may be vacant and takes Na and K  X= Ca, Mg, Fe, Na; Y=

AMPHIBOLES (double chains)  General formula:  X 2 Y 5 Z 8 O 22 (OH) 2 the box is a site that may be vacant and takes Na and K  X= Ca, Mg, Fe, Na; Y=
What is a rock? A rock is a combination of minerals. For example: Granite is composed of biotite, quartz, and feldspar.

What is a rock? A rock is a combination of minerals. For example: Granite is composed of biotite, quartz, and feldspar.
Muscovite By Tiffany Yesavage. muscovite Muscovite is a dioctahedral mica. Only two octahedra are occupied and the third octahedron is vacant. However,

Muscovite By Tiffany Yesavage. muscovite Muscovite is a dioctahedral mica. Only two octahedra are occupied and the third octahedron is vacant. However,
Minerals A. Changing scales to looking at the elements of the earth and its crust (8 most common) B. Introduction to minerals that comprise rocks (11 most.

Minerals A. Changing scales to looking at the elements of the earth and its crust (8 most common) B. Introduction to minerals that comprise rocks (11 most.
Six-sided, pyramidal Quartz Crystals.

Six-sided, pyramidal Quartz Crystals.
Use of the petrographic microscope

Use of the petrographic microscope
Edward J. Tarbuck & Frederick K. Lutgens

Edward J. Tarbuck & Frederick K. Lutgens
Lecture 20 (12/06/2006) Systematic Description of Minerals Part 4: Silicates II: Cyclosilicates, Inosilicates, Phyllosilicates and Tectosilicates.

Lecture 20 (12/06/2006) Systematic Description of Minerals Part 4: Silicates II: Cyclosilicates, Inosilicates, Phyllosilicates and Tectosilicates.
Atoms, Compounds, Minerals and Rocks. Atoms Atoms - the smallest unit of an element that retains the physical and chemical properties of that element.

Atoms, Compounds, Minerals and Rocks. Atoms Atoms - the smallest unit of an element that retains the physical and chemical properties of that element.
Sheet Silicates Abundant and common minerals throughout upper 20 km of crust Abundant and common minerals throughout upper 20 km of crust Felsic to intermediate.

Sheet Silicates Abundant and common minerals throughout upper 20 km of crust Abundant and common minerals throughout upper 20 km of crust Felsic to intermediate.
MINERALS. Chemical composition of the Crust n Oxygen most abundant- 46.6% n Followed by silicon and aluminum n Iron, Calcium, Sodium, Potassium, Magnesium.

MINERALS. Chemical composition of the Crust n Oxygen most abundant- 46.6% n Followed by silicon and aluminum n Iron, Calcium, Sodium, Potassium, Magnesium.
Minerals: Building Blocks of Rocks Chapter 2

Minerals: Building Blocks of Rocks Chapter 2
CHUNKY MINERALS. 5 PARTS TO THE DEFINITION OF A MINERAL 1. Not man made Answer: Naturally occurring.

CHUNKY MINERALS. 5 PARTS TO THE DEFINITION OF A MINERAL 1. Not man made Answer: Naturally occurring.
CEE 437 Lecture 2 Minerals Thomas Doe. Topics Mineral Definition Rock Forming Minerals Physical Proprieties of Minerals Mineral Identification Mineral.

CEE 437 Lecture 2 Minerals Thomas Doe. Topics Mineral Definition Rock Forming Minerals Physical Proprieties of Minerals Mineral Identification Mineral.
Building Soil Minerals. EXPECTED ION CORRDINATION.

Building Soil Minerals. EXPECTED ION CORRDINATION.
MINERALS AND ROCKS COMPOSITION, ORIGIN AND IDENTIFICATION COPOYRIGHT 2002, TERRY WRIGHT.

MINERALS AND ROCKS COMPOSITION, ORIGIN AND IDENTIFICATION COPOYRIGHT 2002, TERRY WRIGHT.
Rocks are aggregates of minerals. Many are silicate minerals. This granite, an igneous rock, has Quartz, an amphibole called Hornblende, a pink potassium.

Rocks are aggregates of minerals. Many are silicate minerals. This granite, an igneous rock, has Quartz, an amphibole called Hornblende, a pink potassium.
MINERALS. Chemical composition of the Crust n Oxygen most abundant- 46.6% n Followed by silicon and aluminum n Iron, Calcium, Sodium, Potassium, Magnesium.

MINERALS. Chemical composition of the Crust n Oxygen most abundant- 46.6% n Followed by silicon and aluminum n Iron, Calcium, Sodium, Potassium, Magnesium.

Similar presentations

Ads by Google