Clay: Difference between revisions

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== Characteristics of Clay ==
== Characteristics of Clay ==
[[File:Clay size.jpg|thumb|Clay Size Relative to silt and Sand]]
[[File:Clay size.jpg|thumb|Clay Size Relative to silt and Sand]]
For something to be considered clay it has to met a few criteria. The grain size of a clay particle has to be 0.002mm or smaller, this means greater surface area, and that the clay particles will be tightly packed. Clay also has to have the ability to absorb water from the [[soil|soil]]. Its particles will increase there size greatly when they absorb water, sometimes by nearly 100 percent. Clay has to be made of hydrous aluminum silicates, these are the chemicals that will be able to absorb water. There are other chemicals in clay but they can be made of whatever other material that is available and has also been broken down in erosion and weathering.
In order to be classified as a clay, the particles must meet certain criteria. The grain size must be less than .002mm, resulting in a very high surface area. Clays have the ability to bond with water from the [[soil]] due to their molecular structures. Clays are made up of various minerals which are classified as hydrous aluminum phyllosilicates. These minerals may be iron, alkali metals, alkaline earths or other cations that may be found in the surrounding soil. The basic structure of the phyllosilicates is based on interconnected six member rings of SiO4-4 tetrahedra that extend outward in infinite sheets. Phyllosilicates may contain additional molecules such as hydroxyl ions and cations. This results in two basic groups of sheet silicates:
 
1. The trioctahedral sheet silicates where each O or OH ion is surrounded by 3 divalent cations, like Mg+2 or Fe+2.
 
2. The dioctahedral sheet silicates where each O or OH ion is surrounded by 2 trivalent cations, usually Al+3.
 
These molecular structures and build upon themselves, resulting in sheet minerals such as talcs and micas. These minerals can be found in parent rocks and serve as the structural basis of clays, which allow them the ability to bond with water. This characteristic is essential to plant and animal life in soils, and these porous spaces between clay grains facilitate the creation of microhabitats and communities that contribute to the complexity and heterogeneity of [[soil]].


== Residual Clay ==
== Residual Clay ==

Revision as of 12:16, 17 April 2019

Origins of Clay

Weathering and Erosion of Rocks

Clay is formed from the erosion of a limited variety of environments. Some of these environments include; continental which is weathering and erosion on Earth's surface, marine which occurs on the floor of a body of water, or even within the Earth when it is near a heat source. The heat source would be magma, and there would have to be water in the pores of the rocks and minerals under the crust of the Earth. When the situations are right the clay is formed by the breaking down of the minerals. Clay can include any minerals of the rocks that it breaks down to form clay soil but there has to be some minerals in it that are able to absorb water. In order for something to be a considered a clay it also has to be smaller than 0.002mm. There are 2 main types of clay residual and sedimentary clays. When clay is formed there is the chemical decomposition of feldspar.

Characteristics of Clay

Clay Size Relative to silt and Sand

In order to be classified as a clay, the particles must meet certain criteria. The grain size must be less than .002mm, resulting in a very high surface area. Clays have the ability to bond with water from the soil due to their molecular structures. Clays are made up of various minerals which are classified as hydrous aluminum phyllosilicates. These minerals may be iron, alkali metals, alkaline earths or other cations that may be found in the surrounding soil. The basic structure of the phyllosilicates is based on interconnected six member rings of SiO4-4 tetrahedra that extend outward in infinite sheets. Phyllosilicates may contain additional molecules such as hydroxyl ions and cations. This results in two basic groups of sheet silicates:

1. The trioctahedral sheet silicates where each O or OH ion is surrounded by 3 divalent cations, like Mg+2 or Fe+2.

2. The dioctahedral sheet silicates where each O or OH ion is surrounded by 2 trivalent cations, usually Al+3.

These molecular structures and build upon themselves, resulting in sheet minerals such as talcs and micas. These minerals can be found in parent rocks and serve as the structural basis of clays, which allow them the ability to bond with water. This characteristic is essential to plant and animal life in soils, and these porous spaces between clay grains facilitate the creation of microhabitats and communities that contribute to the complexity and heterogeneity of soil.

Residual Clay

Residual clay is clay that has not been transported away from the parent rock. This type of clay is most often formed from weathering on the earths surface, which can happen in a few different ways. One way is that it can have chemical deposition of rocks, like granite. Another is, solutions of rocks like limestone have impurities but can be deposited as clay. Once this happens residual clay is formed and can then be harvested for different uses. Residual clay is considered to have low plasticity and will not stick together very easily which, limits its uses.

Sedimentary Clay

MacroFauna

Sedimentary clay are minerals that broke down from the original parent material, through weathering and erosion. They are then transported by wind, water, ice, or any other mode of transport away from the parent rock. As these particles are being transported the are suspended in the water because they are so small. They will only be deposited when the clay particles bump into each other causing them to stick together and sink down to the bottom of the river. When they get moved there are eroded further causing them to decrease in there size. This type of clay is considered to have more plasticity this means it will form a sticker soil.

Organisms That Live in Clay

Microfauna

Clay is not very suitable for many plants to live in, as air has a hard time getting through the soil to the roots because the soil is packed so tightly. There is also a drainage problem with clay dominate soils. Some plants that can tolerate this conditions are coniferous trees such as; pine trees, spruce, balsam fir, and tamarack trees to name a few. Some deciduous trees also can grow in clay dominate soils like; willows, crabapple trees, and some maples. There are also some organisms that live within the predominantly clay soil as well. From, macro-fauna like earthworms and insects to micro-fauna like bacteria, nematodes, and other microscopic organisms can live within clay soil. In order for most things to grow in clay soil you would need to till in peat moss into the soil. Peat moss will increase the carbon content in the soil and help plants to be able to grow much better.

Mesofauna











References

"Clay Types, Geology, Properties and Color Chart (GcCeramics) - Meeneecat." Google Sites. N.p., n.d. Web. 14 Apr. 2018.


"Earth Sciences: London's Geology." Clays and Clay Minerals. N.p., n.d. Web. 14 Apr. 2018.


"How Is Clay Formed? Is It Inorganic or Organic?" The Clay Ground Collective. N.p., n.d. Web. 14 Apr. 2018.


"Trees and Shrubs for Clay Soil." Trees and Shrubs for Clay Soil : UMN Extension. N.p., n.d. Web. 14 Apr. 2018.


Environmental Characteristics of Clays and Clay Mineral Deposits. N.p., n.d. Web. 14 Apr. 2018.


Kodama, Hideomi, and Ralph E. Grim. "Clay Mineral." Encyclopædia Britannica. Encyclopædia Britannica, Inc., 20 Feb. 2014. Web. 14 Apr. 2018.