User:Glossic-hapludalf/soil color sandbox

Soil color    is often the most visually apparent property of soil. While color itself does not influence the behavior or practical use of soils, it does indicate important information about the soil organic matter content, mineralogy, moisture, and drainage.

Soil can display a wide range of colors including brown, red, yellow, black, gray, white, and even blue or green, and vary dramatically across landscapes, between the various horizons of a soil profile, and even within a single clod of soil.

The development and distribution of color in soil results from chemical and biological weathering, especially redox reactions. As the primary minerals in soil parent material weather, the elements combine into new and colorful compounds. Soil conditions produce uniform or gradual color changes, while reducing environments result in disrupted color flow with complex, mottled patterns and points of color concentration. Sometimes, a distinct change in color within a soil profile indicates a change in the soil parent material or mineral origin.

Dark brown or black
Dark brown or black colors typically indicate that the soil has a high organic matter content. Organic matter coats mineral soil particles, which masks or darkens the natural mineral colors.

Sodium content also influences the depth of organic matter and therefore the soil color. Sodium causes organic matter particles such as humus to disperse more readily and reach more minerals. Additionally, soils which accumulate charcoal exhibit a black color.

Red
Red colors often indicate iron accumulation or oxidation in oxygen-rich, well-aerated soils. Iron concentrations caused by redox reactions in periodically saturated soils may also present red colors, particularly along root channels or pores.

Gray or blue
Soil in anaerobic, saturated environments may appear gray or blue in color due to the redox reduction and/or depletion of iron. In an anaerobic soils, microbes reduce iron from the ferric (Fe3+) to the ferrous (Fe2+) form. Manganese may also be reduced from the manganic (Mn4+) to the manganous (Mn2+) form, though iron reduction is more common in soil. The reduced iron compounds cause poorly drained soil to appear gray or blue, and because reduced iron is soluble in water, it may be removed from the soil during prolonged saturation. This often exposes the light gray colors of bare silicate minerals, and soils with a low chroma from iron reduction or depletion are said to be gleyed.

Green
Iron reduction may impart greenish gray colors, though certain minerals including glauconite and melanterite can also give soil a green color. Glauconite soils form in select marine sedimentary rocks, while melanterite soils are produced in acidic, pyrite-rich soils.

Yellow
Yellow soils may indicate iron accumulation as well, though in less oxygen-rich environments than red soils. Jarosite accumulation can also create yellow soil color and may be found in salt marshes, sulfide ore deposits, acid mine tailings, and other acidic soils.

White
White colors are common in soils with salt, carbonate, or calcite accumulations, which often occur in arid environments.



Description
Most soil survey organizations utilize the Munsell color system to decrease the subjectivity inherent to evaluating color. This system was developed by Albert Munsell, a painter, in the early 20th century to describe the full color spectrum, though the specially adapted Munsell soil color books commonly used by soil scientists only include the most relevant colors for soil.

The Munsell color system includes the following three components:


 * Hue: indicates the dominant spectral (i.e., rainbow) color, which in soil is generally yellow and/or red. Each page of the Munsell soil color book displays a different hue. Examples include 10YR, 5YR, and 2.5Y.
 * Value: indicates lightness or darkness. Value increases from the bottom of each page to the top, with lower numbers representing darker color. Color with a value of 0 would be black.
 * Chroma: indicates intensity or brightness. Chroma increases from left to right on each page, with higher numbers representing more vivid or saturated color. Color with a chroma of 0 would be neutral gray.

A general color name, such as yellowish brown or light gray, often accompanies the Munsell notation for soil samples. These qualitative descriptors correspond to one or more color chips in the Munsell soil color books; however, they are not formally part of the broader Munsell color system.

Because soil color (specifically the value) varies with moisture, it may be described at both its moist and dry state. Soil is considered moist when adding water no longer changes the soil color, or as "dry" when the soil is air dry.