Difference between revisions of "Clay" - New World Encyclopedia
Rosie Tanabe (talk | contribs) |
|||
| (11 intermediate revisions by 6 users not shown) | |||
| Line 1: | Line 1: | ||
| − | {{Images OK}}{{Submitted}}{{Approved}} | + | {{Copyedited}}{{Paid}}{{Images OK}}{{Submitted}}{{Approved}} |
| + | [[Category:Public]] | ||
[[Image:Gay head cliffs MV.JPG|right|thumb|250px|These cliffs in Martha's Vineyard, Massachusetts, are made almost entirely of clay.]] | [[Image:Gay head cliffs MV.JPG|right|thumb|250px|These cliffs in Martha's Vineyard, Massachusetts, are made almost entirely of clay.]] | ||
'''Clay''' is a term used to describe a group of fine-grained, silicate minerals known as [[aluminum]] phyllosilicates, containing variable amounts of chemically associated [[water]]. | '''Clay''' is a term used to describe a group of fine-grained, silicate minerals known as [[aluminum]] phyllosilicates, containing variable amounts of chemically associated [[water]]. | ||
| − | Clay is plastic when wet, which means it can be easily shaped. When dry, it becomes firm, and when subject to high temperature, known as ''firing'', permanent physical and chemical | + | Clay is [[plastic]] when wet, which means it can be easily shaped. When dry, it becomes firm, and when subject to high temperature, known as ''firing'', permanent physical and chemical changes occur. These changes cause the clay to be hardened. A fireplace or oven specifically designed for hardening clay is called a ''[[kiln]]''. |
| − | Clay soils are distinguished from other types of soil such as [[silt]] by the small grain size, flake or layered shape, affinity for water, and high degree of plasticity. The grain size of clay is typically less than | + | Clay soils are distinguished from other types of soil such as [[silt]] by the small grain size, flake or layered shape, affinity for water, and high degree of plasticity. The grain size of clay is typically less than two micrometers (μm) in [[diameter]]. Depending on the content of the soil, clay can appear in various colors, from a dull gray to a deep orange-red. |
| − | + | {{toc}} | |
| − | People discovered the useful properties of clay in prehistoric times, and one of the earliest artifacts ever uncovered is a drinking vessel made of sun-dried clay. Clays remain among the cheapest and most widely used materials, to make items ranging from art objects to bricks and cookware. They are also used in industrial processes such as [[paper]]making and | + | [[human being|People]] discovered the useful properties of clay in prehistoric times, and one of the earliest artifacts ever uncovered is a drinking vessel made of sun-dried clay. Clays remain among the cheapest and most widely used materials, to make items ranging from art objects to bricks and cookware. They are also used in industrial processes such as [[paper]]making and cement production. An open mine for extracting clay is called a ''clay pit''. |
== Clay minerals == | == Clay minerals == | ||
| − | Clay minerals are rich in [[silicon]] and [[aluminum]] [[oxide]] | + | Clay minerals are rich in [[silicon]] and [[aluminum]] [[oxide]]s and [[hydroxide]]s, and sometimes contain variable amounts of [[iron]], [[magnesium]], [[alkali metal]]s, [[alkaline earth]]s, and other [[ion (physics)|cation]]s. Clays have structures similar to the micas and therefore form flat, hexagonal sheets. |
| − | Clays are generally formed by the chemical [[weathering]] | + | Clays are generally formed by the chemical [[weathering]] of silicate-bearing rocks by [[carbonic acid]], but some are formed by [[hydrothermal]] activity. Clay [[mineral]]s are common in fine-grained sedimentary rocks such as [[shale]], [[mudstone]], and [[siltstone]], and in fine-grained metamorphic [[slate]] and [[phyllite]]. |
Clay minerals include the following groups: | Clay minerals include the following groups: | ||
| − | * Kaolinite group, which includes the minerals [[kaolinite]] | + | * Kaolinite group, which includes the minerals [[kaolinite]], [[dickite]], [[halloysite]], and [[nacrite]]. |
| − | ** Some sources include the [[serpentine]] | + | ** Some sources include the [[serpentine]] group, based on structural similarities (Bailey, 1980). |
| − | * Smectite group, which includes [[pyrophyllite]] | + | * Smectite group, which includes [[pyrophyllite]], [[talc]], [[vermiculite]], [[sauconite]], [[saponite]], [[nontronite]], and [[montmorillonite]]. |
| − | * Illite group, which includes the clay-micas. [[Illite]] | + | * Illite group, which includes the clay-micas. [[Illite]] is the only common mineral in this group. |
| − | * [[Chlorite group]] | + | * [[Chlorite group]], which includes a wide variety of similar minerals with considerable chemical variation. This group is not always considered a part of the clays and is sometimes classified as a separate group within the phyllosilicates. |
There are about 30 different types of 'pure' clays in these categories, but most clays in nature are mixtures of these different types, along with other weathered minerals. | There are about 30 different types of 'pure' clays in these categories, but most clays in nature are mixtures of these different types, along with other weathered minerals. | ||
| − | [[Varve]] | + | [[Varve]] (or ''varved clay'') is clay with visible annual layers, formed by seasonal differences in erosion and organic content. This type of deposit is common in former [[glacial lake]]s from the [[Ice Age]]. |
| − | [[Quick clay]] | + | [[Quick clay]] is a unique type of [[marine clay]], indigenous to the glaciated terrains of [[Norway]], [[Canada]], and [[Sweden]]. It is a highly sensitive clay, prone to [[liquefaction]], and it has been involved in several deadly [[landslides]]. |
=== Structure === | === Structure === | ||
| − | Like all phyllosilicates, clay minerals are characterised by two-dimensional ''sheets'' of corner-sharing tetrahedra made of SiO<sub>4</sub> and AlO<sub>4</sub>. Each tetrahedron shares | + | Like all phyllosilicates, clay minerals are characterised by two-dimensional ''sheets'' of corner-sharing tetrahedra made of SiO<sub>4</sub> and AlO<sub>4</sub>. Each tetrahedron shares three of its vertex oxygen atoms with other tetrahedra. The fourth vertex is not shared with another tetrahedron and all of the tetrahedra "point" in the same direction—in other words, all the unshared vertices lie on the same side of the sheet. These tetrahedral sheets have the chemical composition (Al,Si)<sub>3</sub>O<sub>4</sub>. |
| − | In clays, the tetrahedral sheets are always bonded to octahedral sheets. The latter are formed from small cations, such as aluminum or magnesium cations, coordinated by six oxygen atoms. The unshared vertex from the tetrahedral sheet also forms part of one side of the octahedral sheet, but an additional oxygen atom is located above the gap in the tetrahedral sheet at the center of the six tetrahedra. This oxygen atom is bonded to a hydrogen atom forming an OH group in the clay structure. | + | In clays, the tetrahedral sheets are always bonded to octahedral sheets. The latter are formed from small cations, such as aluminum or magnesium cations, coordinated by six [[oxygen]] [atom|atoms]]. The unshared vertex from the tetrahedral sheet also forms part of one side of the octahedral sheet, but an additional oxygen atom is located above the gap in the tetrahedral sheet at the center of the six tetrahedra. This oxygen atom is bonded to a hydrogen atom forming an OH (hydroxide) group in the clay structure. |
Clays can be categorized according to the way that the tetrahedral and octahedral sheets are packaged into "layers." If each layer consists of only one tetrahedral and one octahedral group, the clay is known as a 1:1 clay. Likewise, a 2:1 clay has two tetrahedral sheets, with the unshared vertex of each sheet pointing toward each other and forming each side of the octahedral sheet. | Clays can be categorized according to the way that the tetrahedral and octahedral sheets are packaged into "layers." If each layer consists of only one tetrahedral and one octahedral group, the clay is known as a 1:1 clay. Likewise, a 2:1 clay has two tetrahedral sheets, with the unshared vertex of each sheet pointing toward each other and forming each side of the octahedral sheet. | ||
| − | Depending on the composition of the tetrahedral and octahedral sheets, the layer will have no electric charge or will have a net negative charge. If the layers are charged, this charge is balanced by interlayer cations such as Na<sup>+</sup> or K<sup>+</sup>. In each case the interlayer can also contain water. The crystal structure is formed from a stack of layers interspaced with the interlayers. | + | Depending on the composition of the tetrahedral and octahedral sheets, the layer will have no [[electron|electric]] charge or will have a net negative charge. If the layers are charged, this charge is balanced by interlayer cations such as Na<sup>+</sup> or K<sup>+</sup>. In each case the interlayer can also contain water. The crystal structure is formed from a stack of layers interspaced with the interlayers. |
== Uses of clay == | == Uses of clay == | ||
[[Image:Clay-ss-2005.jpg|thumb|Quaternary clay in Estonia.]] | [[Image:Clay-ss-2005.jpg|thumb|Quaternary clay in Estonia.]] | ||
| − | The properties of clay make it an ideal material for producing durable [[pottery]] items for both practical and decorative purposes. By using different types of clay and firing conditions, one can produce [[earthenware]] | + | The properties of clay make it an ideal material for producing durable [[pottery]] items for both practical and decorative purposes. By using different types of clay and firing conditions, one can produce [[earthenware]], [[stoneware]], and [[porcelain]]. |
| − | Clays [[ | + | Clays sintered in [[fire]] were the first type of [[ceramic]]. They continue to be widely used, to produce such items as [[brick]]s, cooking pots, art objects, and [[dishware]]. Even some musical instruments, such as the [[ocarina]],are made with clay. Industrial processes that involve the use of clay include [[paper]]making, [[cement]] production, [[pottery]] manufacture, and chemical filtration. |
==See also== | ==See also== | ||
| Line 56: | Line 57: | ||
* [http://www.minsocam.org/msa/collectors_corner/arc/nomenclaturecl1.htm Clay mineral nomenclature] ''American Mineralogist''. | * [http://www.minsocam.org/msa/collectors_corner/arc/nomenclaturecl1.htm Clay mineral nomenclature] ''American Mineralogist''. | ||
| − | * | + | * ''Clay Mineral Group'' Mineral Galleries] |
*[http://www.minsocam.org/msa/collectors_corner/arc/nomenclaturecl1.htm Bailey, S. W., 1980, ''Summary of recommendations of AIPEA nomenclature committee on clay minerals'', American Mineralogist Volume 65, pages 1-7.] Accessed Jan. 2, 2006 | *[http://www.minsocam.org/msa/collectors_corner/arc/nomenclaturecl1.htm Bailey, S. W., 1980, ''Summary of recommendations of AIPEA nomenclature committee on clay minerals'', American Mineralogist Volume 65, pages 1-7.] Accessed Jan. 2, 2006 | ||
| − | |||
| − | |||
| − | |||
| − | + | ||
[[Category:Physical sciences]] | [[Category:Physical sciences]] | ||
Latest revision as of 11:01, 19 December 2023
Clay is a term used to describe a group of fine-grained, silicate minerals known as aluminum phyllosilicates, containing variable amounts of chemically associated water. Clay is plastic when wet, which means it can be easily shaped. When dry, it becomes firm, and when subject to high temperature, known as firing, permanent physical and chemical changes occur. These changes cause the clay to be hardened. A fireplace or oven specifically designed for hardening clay is called a kiln.
Clay soils are distinguished from other types of soil such as silt by the small grain size, flake or layered shape, affinity for water, and high degree of plasticity. The grain size of clay is typically less than two micrometers (μm) in diameter. Depending on the content of the soil, clay can appear in various colors, from a dull gray to a deep orange-red.
People discovered the useful properties of clay in prehistoric times, and one of the earliest artifacts ever uncovered is a drinking vessel made of sun-dried clay. Clays remain among the cheapest and most widely used materials, to make items ranging from art objects to bricks and cookware. They are also used in industrial processes such as papermaking and cement production. An open mine for extracting clay is called a clay pit.
Clay minerals
Clay minerals are rich in silicon and aluminum oxides and hydroxides, and sometimes contain variable amounts of iron, magnesium, alkali metals, alkaline earths, and other cations. Clays have structures similar to the micas and therefore form flat, hexagonal sheets.
Clays are generally formed by the chemical weathering of silicate-bearing rocks by carbonic acid, but some are formed by hydrothermal activity. Clay minerals are common in fine-grained sedimentary rocks such as shale, mudstone, and siltstone, and in fine-grained metamorphic slate and phyllite.
Clay minerals include the following groups:
- Kaolinite group, which includes the minerals kaolinite, dickite, halloysite, and nacrite.
- Some sources include the serpentine group, based on structural similarities (Bailey, 1980).
- Smectite group, which includes pyrophyllite, talc, vermiculite, sauconite, saponite, nontronite, and montmorillonite.
- Illite group, which includes the clay-micas. Illite is the only common mineral in this group.
- Chlorite group, which includes a wide variety of similar minerals with considerable chemical variation. This group is not always considered a part of the clays and is sometimes classified as a separate group within the phyllosilicates.
There are about 30 different types of 'pure' clays in these categories, but most clays in nature are mixtures of these different types, along with other weathered minerals.
Varve (or varved clay) is clay with visible annual layers, formed by seasonal differences in erosion and organic content. This type of deposit is common in former glacial lakes from the Ice Age.
Quick clay is a unique type of marine clay, indigenous to the glaciated terrains of Norway, Canada, and Sweden. It is a highly sensitive clay, prone to liquefaction, and it has been involved in several deadly landslides.
Structure
Like all phyllosilicates, clay minerals are characterised by two-dimensional sheets of corner-sharing tetrahedra made of SiO4 and AlO4. Each tetrahedron shares three of its vertex oxygen atoms with other tetrahedra. The fourth vertex is not shared with another tetrahedron and all of the tetrahedra "point" in the same direction—in other words, all the unshared vertices lie on the same side of the sheet. These tetrahedral sheets have the chemical composition (Al,Si)3O4.
In clays, the tetrahedral sheets are always bonded to octahedral sheets. The latter are formed from small cations, such as aluminum or magnesium cations, coordinated by six oxygen [atom|atoms]]. The unshared vertex from the tetrahedral sheet also forms part of one side of the octahedral sheet, but an additional oxygen atom is located above the gap in the tetrahedral sheet at the center of the six tetrahedra. This oxygen atom is bonded to a hydrogen atom forming an OH (hydroxide) group in the clay structure.
Clays can be categorized according to the way that the tetrahedral and octahedral sheets are packaged into "layers." If each layer consists of only one tetrahedral and one octahedral group, the clay is known as a 1:1 clay. Likewise, a 2:1 clay has two tetrahedral sheets, with the unshared vertex of each sheet pointing toward each other and forming each side of the octahedral sheet.
Depending on the composition of the tetrahedral and octahedral sheets, the layer will have no electric charge or will have a net negative charge. If the layers are charged, this charge is balanced by interlayer cations such as Na+ or K+. In each case the interlayer can also contain water. The crystal structure is formed from a stack of layers interspaced with the interlayers.
Uses of clay
The properties of clay make it an ideal material for producing durable pottery items for both practical and decorative purposes. By using different types of clay and firing conditions, one can produce earthenware, stoneware, and porcelain.
Clays sintered in fire were the first type of ceramic. They continue to be widely used, to produce such items as bricks, cooking pots, art objects, and dishware. Even some musical instruments, such as the ocarina,are made with clay. Industrial processes that involve the use of clay include papermaking, cement production, pottery manufacture, and chemical filtration.
See also
ReferencesISBN links support NWE through referral fees
- Clay mineral nomenclature American Mineralogist.
- Clay Mineral Group Mineral Galleries]
- Bailey, S. W., 1980, Summary of recommendations of AIPEA nomenclature committee on clay minerals, American Mineralogist Volume 65, pages 1-7. Accessed Jan. 2, 2006
Credits
New World Encyclopedia writers and editors rewrote and completed the Wikipedia article in accordance with New World Encyclopedia standards. This article abides by terms of the Creative Commons CC-by-sa 3.0 License (CC-by-sa), which may be used and disseminated with proper attribution. Credit is due under the terms of this license that can reference both the New World Encyclopedia contributors and the selfless volunteer contributors of the Wikimedia Foundation. To cite this article click here for a list of acceptable citing formats.The history of earlier contributions by wikipedians is accessible to researchers here:
The history of this article since it was imported to New World Encyclopedia:
Note: Some restrictions may apply to use of individual images which are separately licensed.
