Minerals

A mineral can be defined as a naturally occurring inorganic solid that possesses an orderly internal structure and a definite chemical composition. Some people, like physicists, might be guilty of picking up a rock and calling it a mineral. The term "rock" is less specific, referring to any solid mass of mineral or mineral-like material. Common rocks are often made up of crystals of several kinds of minerals. There are some substances, like opal, which have the appearance of a mineral but lack any definite internal structure, are sometimes called "mineraloids". Lutgens and Tarbuck give the following list of essential characteristics of a "mineral":

It must occur naturally.
It must be inorganic
It must be a solid
It must possess an orderly internal structure, that is, its atoms must be arranged in a definite pattern.
It must have a definite chemical composition that may vary within specified limits."

The most common minerals are the silicates, as one would guess by looking at the abundances of the elements in the Earth's crust, but there is a great variety of minerals. Minerals are classified in many ways, including hardness, optical properties, crystal structure, etc. Shipman, et al. comment that over 2000 minerals have been found in the Earth's crust, but that about 20 of them are common and fewer than 10 account for over 90% of the crust by mass.

Non-silicates constitute less than 10% of the Earth's crust. The most common non-silicates are the carbonates, the oxides, and the sulfides. There are also naturally occuring phosphates and salts. There are a few elements which occur in pure form, including gold, silver, copper, bismuth, arsenic, lead and tellurium. Carbon is found in both graphite and diamond form.

Gypsum	Halite	Quartz	Celestite	Stibnite
Hematite	Mica	Feldspar	Rutile	Gold
Galena	Malachite	Azurite	Copper	Sulfur
Millerite	Talc	Barite	Pyrite	Silver
Beryl	Aquamarine	Emerald	Rhodochrosite	Ruby
Fluorite	Calcite	Almandine	Dravite	Turquoise
Danburite	Diamond	Dolomite	Elbaite	Epidote
Ferroaxinite	Fluorapatite	Garnet	Magnetite	Powellite
Sapphire	Scolecite	Topaz	Vanadinite	Vivianite
Wulfenite	Smithsonite	Zircon	Strontianite	Parisite
Phosgenite	Hulsite	Weloganite	Siderite	Magnesite
Aragonite	Witherite	Callaghanite	Pyroaurite	Szaibelyite
Bensonite	Boracite	Weloganite	Artenite	Plattnerite
Brucite	Spinel	Pyrochroite	Brookite	Anatase
Pyrolusite	Ilmenite	Valentinite	Hibonite	Pseudobrookite
Delafossite	Birnessite	Montroydite	Romanechite	Lepidocrocite
Chromite	Aeschynite	Cassiterite	Goethite	Hausmannite
Ramsdellite	Bixbyite	Senarmontite	Senaite	Emplectite
Jamesonite	Stephanite	Zinkenite	Tetrahedrite	Miargyrite
Plagionite	Sphalerite	Bornite	Enargite	Pyrargyrite
Jordanite	Semseyite	Cylindrite	Nagyagite	Boulangerite
Gersdorffite	Berthierite	Bournonite	Dufrenoysite	Tennantite
Dyscrasite	Arsenopyrite	Andorite	Betekhtinite	Carrollite
Gratonite	Acanthite	Ullmannite	Stibarsen	Awaruite
Sperrylite	Glaucodot	Wurtzite	Cubanite	Hutchinsonite
Safflorite	Krennerite	Kermesite	Hessite	Digenite
Pyrrhotite	Linnaeite	Clausthalite	Chalcocite	Chalcopyrite
Chalcostibite	Alabandite	Beudantite	Cuprite	Bayldonite
Olivenite	Adamite	Ludlockite	Mimetite	Scorodite
Germanite	Reinerite	Willemite	Cerussite	Anglesite
Charoite	Reinerite	Tremolite	Riebeckite	Chrysotile
Grunerite	Wollastonite	Pyroxmangite	Rhodonite	Chondrodite
Vesuvianite	Wiluite	Spessartine	Grossular	Andradite
Anorthite	Hyalophane	Labradorite	Albite	Margarite
Penninite	Clintonite	Antigorite	Pyrophyllite	Muscovite

Selection of common minerals

Index

References
Lutgens & Tarbuck
Ch 2

Shipman, et al.
Ch 21

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Carbonates

The carbonate ion (CO₃^2-) can bond with a variety of other ions to produce the carbonate minerals. The bonding with calcium to form the mineral calcite produces one of the most abundant of the non-silicate minerals. All carbonates have the property of dissolving easily in acidic water.

Carbonates
Calcite	Azurite	Malachite	Rhodochrosite	Dolomite
Smithsonite	Strontianite	Phosgenite	Siderite	Magnesite
Weloganite	Aragonite	Pyroaurite	Bensonite	Witherite
Callaghanite	Artenite	Cerussite	Bensonite	Witherite

Index

Reference
Lutgens & Tarbuck
Ch 2

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Oxides

Oxygen, the most abundant element in the Earth's crust, bonds readily with a number of metallic ions to form the oxides. These oxides form important ores for the metal resources.

Oxides
Hematite	Rutile	Powellite	Wulfenite	Ruby
Sapphire	Plattnerite	Spinel	Brookite	Anatase
Pyrolusite	Ilmenite	Valentinite	Magnetite	Montroydite
Romanechite	Chromite	Aeschynite	Cassiterite	Goethite
Haussmanite	Ramsdellite	Bixbyite	Senarmontite	Senaite

Index

Reference
Lutgens & Tarbuck
Ch 2

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Sulfides and Sulfates

Sulfur ions (S^2- ) bind with a number of positive ions to form the sulfide minerals. Many of them are important ores for the ions to which they bind.

Sulfides
Galena	Millerite	Pyrite	Emplectite	Stibnite
Jamesonite	Stephanite	Zinkenite	Tetrahedrite	Miargyrite
Plagionite	Sphalerite	Bornite	Enargite	Pyrargyrite
Jordanite	Semseyite	Cylindrite	Nagyagite	Boulangerite
Gersdorffite	Berthierite	Bournonite	Dufrenoysite	Tennantite
Arsenopyrite	Andorite	Betekhtinite	Carrollite	Gratonite
Acanthite	Ullmannite	Glaucodot	Wurtzite	Cubanite
Hutchinsonite	Kermesite	Glaucodot	Digenite	Pyrrhotite
Linnaeite	Chalcocite	Chalcopyrite	Chalcostibite	Alabandite
Germanite	Chalcocite	Chalcopyrite	Chalcostibite	Alabandite
Sulfates
Gypsum	Barite	Beudantite	Celestite	Anglesite

Index

Reference
Lutgens & Tarbuck
Ch 2

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Phosphates

Phosphorous in the form of phosphate ions (PO₄^3- ) binds with positive ions to form the phosphate minerals.

Phosphates
Vivianite	Fluorapatite	...	...	...

Index

Reference
Lutgens & Tarbuck
Ch 2

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