magnetite n : an oxide of iron that is strongly attracted by magnets [syn: magnetic iron-ore]
ferrimagnetic mineral with chemical formula Fe3O4, one of several iron oxides and a member of the spinel group. The chemical IUPAC name is iron(II,III) oxide and the common chemical name ferrous-ferric oxide. The formula for magnetite may also be written as FeO·Fe2O3, which is one part wüstite (FeO) and one part hematite (Fe2O3). This refers to the different oxidation states of the iron in one structure, not a solid solution.
The Curie temperature of magnetite is 858 K. Magnetite is the most magnetic of all the naturally occurring minerals on Earth, and these magnetic properties led to lodestone being used as an early form of magnetic compass. Magnetite typically carries the dominant magnetic signature in rocks, and so it has been a critical tool in paleomagnetism, a science important in discovering and understanding plate tectonics. The relationships between magnetite and other iron-rich oxide minerals such as ilmenite, hematite, and ulvospinel have been much studied, as the complicated reactions between these minerals and oxygen influence how and when magnetite preserves records of the Earth's magnetic field.
Magnetite has been very important in understanding the conditions under which rocks form and evolve. Magnetite reacts with oxygen to produce hematite, and the mineral pair forms a buffer that can control oxygen fugacity. Commonly igneous rocks contain grains of two solid solutions, one between magnetite and ulvospinel and the other between ilmenite and hematite. Compositions of the mineral pairs are used to calculate how oxidizing was the magma (i.e., the oxygen fugacity of the magma): a range of oxidizing conditions are found in magmas and the oxidation state helps to determine how the magmas might evolve by fractional crystallization.
Small grains of magnetite occur in almost all igneous rocks and metamorphic rocks. Magnetite also occurs in many sedimentary rocks, including banded iron formations. In many igneous rocks, magnetite-rich and ilmenite-rich grains occur that precipitated together from magma. Magnetite also is produced from peridotites and dunites by serpentinization.
Distribution of depositsMagnetite is sometimes found in large quantities in beach sand. Such mineral sands or iron sands or black sands are found in various places such as California and the west coast of New Zealand. The magnetite is carried to the beach via rivers from erosion and is concentrated via wave action and currents.
Huge deposits have been found in banded iron formations. These sedimentary rocks have been used to infer changes in the oxygen content of the atmosphere of the Earth.
Large deposits of Magnetite also are found in Kiruna, Sweden, the Pilbara region in Western Australia, and in the Adirondack region of New York in the United States. Deposits are also found in Norway, Germany, Italy, Switzerland, South Africa, India, Mexico, and in Oregon, New Jersey, Pennsylvania, North Carolina, Virginia, New Mexico, Utah, and Colorado in the United States. Recently, in June 2005, an exploration company, Cardero Resources, discovered a vast deposit of magnetite-bearing sand dunes in Peru. The dune field covers 250 square kilometers (100 sq mi), with the highest dune at over 2,000 meters (6,560 ft) above the desert floor. The sand contains 10% magnetitehttp://www.321gold.com/editorials/moriarty/moriarty070505.html.
Biological occurrencesCrystals of magnetite have been found in some bacteria (e.g., Magnetospirillum magnetotacticum) and in the brains of bees, of termites, of some birds (e.g., the pigeon), and of humans. These crystals are thought to be involved in magnetoreception, the ability to sense the polarity or the inclination of the Earth's magnetic field, and to be involved in navigation. Also, chitons have teeth made of magnetite on their radula making them unique among animals. This means they have an exceptionally abrasive tongue with which to scrape food from rocks.
The study of biomagnetism began with the discoveries of Caltech paleoecologist Heinz Lowenstam in the 1960s.
Preparation as a ferrofluid
Magnetite can be prepared in the laboratory as a ferrofluid in the Massart method by mixing iron(II) chloride and iron(III) chloride in the presence of sodium hydroxide.
- Heinz A. Lowenstam and Stephen Weiner, On Biomineralization, Oxford University Press, USA (1989) ISBN 0-19-504977-2
- Shih-Bin Robin Chang' and Joseph Lynn Kirschvink, Magnetofossils, the Magnetization of Sediments, and the Evolution of Magnetite Biomineralization, Ann. Rev. Earth Planet. Sci. 1989. 17:169-95 PDF file
- Magnetic bacteria (Italian)
Mining related links
magnetite in Arabic: ماغنتيت
magnetite in Catalan: Magnetita
magnetite in Czech: Magnetit
magnetite in German: Magnetit
magnetite in Estonian: Magnetiit
magnetite in Modern Greek (1453-): Μαγνητίτης
magnetite in Spanish: Magnetita
magnetite in French: Magnétite
magnetite in Galician: Magnetita
magnetite in Croatian: Magnetit
magnetite in Italian: Magnetite
magnetite in Hebrew: מגנטיט
magnetite in Lithuanian: Magnetitas
magnetite in Hungarian: Magnetit
magnetite in Dutch: Magnetiet
magnetite in Japanese: 磁鉄鉱
magnetite in Norwegian: Magnetitt
magnetite in Polish: Magnetyt
magnetite in Portuguese: Magnetita
magnetite in Romanian: Magnetit
magnetite in Russian: Магнетит
magnetite in Slovak: Magnetit
magnetite in Serbian: Магнетит
magnetite in Finnish: Magnetiitti
magnetite in Swedish: Magnetit
magnetite in Ukrainian: Магнетит
magnetite in Chinese: 磁鐵礦