Apatite

Apatite taillée

Thin section microscopy Siilinjärvi R301 6170 apatite

Siilinjärvi Särkijärvi pit

Apatite is a group of phosphate minerals usually referring to hydroxylapatite, fluorapatite, and chlorapatite, with high concentrations of OH−, F−, and Cl− ions, respectively, in the crystal. The formula of the admixture of the three most common endmembers is written as Ca₅(PO₄)₃(OH, F, Cl). Apatite is one of a few minerals produced and used by biological micro-environmental systems. Apatite is the defining mineral for 5 on the Mohs scale of mineral hardness.

Properties and Structure[edit | edit source]

Apatite crystals are hexagonal and can be either tabular or columnar. They often display a hexagonal prism or a bipyramidal shape. The mineral composition of apatite is often complex, with numerous substitutions by similar ions that can lead to a wide variety of colors, ranging from almost every color of the rainbow. This variability in color and the fact that apatite is found in a wide range of environments make it a popular choice among collectors.

Occurrence[edit | edit source]

Apatite is found in a variety of rock types. Igneous rocks, particularly carbonatites and a wide variety of metamorphic rocks, are the primary sources of this mineral. It is also a common byproduct of weathering in phosphate-rich rock, and it can be found in sedimentary rocks as a secondary mineral. In the geological environment, apatite is an important source of phosphorus, a key element for plant life, making it crucial in the formation of phosphate deposits that are mined for their phosphorus content.

Uses[edit | edit source]

Apatite is used in a number of ways, most notably in the manufacture of fertilizer due to its high phosphorus content. It is also used in the production of animal feed supplements and certain chemicals. In the field of gemology, apatite is cut as a gemstone, although its softness and brittleness limit its use in jewelry. In the realm of science and technology, apatite's ability to incorporate a wide variety of elements into its crystal structure makes it useful in the nuclear industry for immobilizing radioactive waste and in the field of biomedicine for bone repair and reconstruction, due to its similarity to human bone mineral.

Biological Significance[edit | edit source]

In biology, apatite has a significant role in the composition of bone and teeth, making it of interest in the field of biomedicine. Hydroxylapatite, the hydroxyl endmember of apatite, is the main mineral component of bone and tooth enamel. Synthetic apatite is often used in orthopedics and dental applications to repair and replace bone material.

Environmental Impact[edit | edit source]

While apatite is crucial for the growth of plants and thus supports life, its mining and processing for use in fertilizers and chemicals can have significant environmental impacts. The extraction process can lead to water pollution and soil degradation, and the release of phosphorus can contribute to the eutrophication of water bodies, leading to algal blooms and anoxic conditions that harm aquatic life.

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