Humus Explained

In classical soil science, humus is the dark organic matter in soil that is formed by the decomposition of plant and animal matter. It is a kind of soil organic matter. It is rich in nutrients and retains moisture in the soil. Humus is the Latin word for "earth" or "ground".[1]

In agriculture, "humus" sometimes also is used to describe mature or natural compost extracted from a woodland or other spontaneous source for use as a soil conditioner.[2] It is also used to describe a topsoil horizon that contains organic matter (humus type,[3] humus form,[4] or humus profile[5]).

Humus has many nutrients that improve the health of soil, nitrogen being the most important. The ratio of carbon to nitrogen (C:N) of humus commonly ranges between 8:1 and 15:1 with the median being about 12:1.[6] It also significantly improves (decreases) the bulk density of soil.[7] Humus is amorphous and lacks the cellular structure characteristic of organisms.[8]

A similar material, also called humus and often used as fertilizer after composting and if not judged contaminated by pathogens, toxic heavy metals, and persistent organic pollutants according to standard tolerance levels,[9] is the solid residue of sewage sludge treatment, which is a secondary phase in the wastewater treatment process.[10]

Description

The primary materials needed for the process of humification are plant detritus and dead animals and microbes, excreta of all soil-dwelling organisms, and also black carbon resulting from past fires.[11] The composition of humus varies with that of primary (plant) materials and secondary microbial and animal products. The decomposition rate of the different compounds will affect the composition of the humus.[12]

It is difficult to define humus precisely because it is a very complex substance which is still not fully understood. Humus is different from decomposing soil organic matter. The latter looks rough and has visible remains of the original plant or animal matter. Fully humified humus, on the contrary, has a uniformly dark, spongy, and jelly-like appearance, and is amorphous; it may gradually decay over several years or persist for millennia.[13] It has no determinate shape, structure, or quality. However, when examined under a microscope, humus may reveal tiny plant, animal, or microbial remains that have been mechanically, but not chemically, degraded.[14] This suggests an ambiguous boundary between humus and soil organic matter, leading some authors to contest the use of the term humus and derived terms such as humic substances or humification, proposing the Soil Continuum Model (SCM).[15] However, humus can be considered as having distinct properties, mostly linked to its richness in functional groups, justifying its maintenance as a specific term.[16]

Fully formed humus is essentially a collection of very large and complex molecules formed in part from lignin and other polyphenolic molecules of the original plant material (foliage, wood, bark), in part from similar molecules that have been produced by microbes.[17] During decomposition processes these polyphenols are modified chemically so that they are able to join up with one another to form very large molecules. Some parts of these molecules are modified in such a way that protein molecules, amino acids, and amino sugars are able to attach themselves to the polyphenol “base” molecule. As protein contains both nitrogen and sulfur, this attachment gives humus a moderate content of these two important plant nutrients.[18]

Radiocarbon and other dating techniques have shown that the polyphenolic base of humus (mostly lignin and black carbon) can be very old, but the protein and carbohydrate attachments much younger, while to the light of modern concepts and methods the situation appears much more complex and unpredictable than previously thought.[19] It seems that microbes are able to pull protein off humus molecules rather more readily than they are able to break the polyphenolic base molecule itself. As protein is removed its place may be taken by younger protein, or this younger protein may attach itself to another part of the humus molecule.[20]

The most useful functions of humus are in improving soil structure, all the more when associated with cations (e.g. calcium),[21] and in providing a very large surface area that can hold nutrient elements until required by plants, an ion exchange function comparable to that of clay particles.[22]

Soil carbon sequestration is a major property of the soil, also considered as an ecosystem service.[23] Only when it becomes stable molecular soil humus and acquires its multi-century permanence should it be considered to be of significance in removing the atmosphere’s current carbon dioxide overload.

There is little data available on the composition of forest humus because it is a complex mixture that is challenging for researchers to analyze. Researchers in the 1940s and 1960s tried using chemical separation to analyze plant and humic compounds in forest soil, but this proved impossible. Further research has been done in more recent years, though it remains an active field of study.[24] [25] [26]

Humification

Microorganisms decompose a large portion of the soil organic matter into inorganic minerals that the roots of plants can absorb as nutrients. This process is termed "mineralization". In this process, nitrogen (nitrogen cycle) and the other nutrients (nutrient cycle) in the decomposed organic matter are recycled. Depending on the conditions in which the decomposition occurs, a fraction of the organic matter does not mineralize and instead is transformed by a process called "humification". Prior to modern analytical methods, early evidence led scientists to believe that humification resulted in concatenations of organic polymer resistant to the action of microorganisms,[27] however recent research has demonstrated that microorganisms are capable of digesting humus.[28]

Humification can occur naturally in soil or artificially in the production of compost. Organic matter is humified by a combination of saprotrophic fungi, bacteria, microbes and animals such as earthworms, nematodes, protozoa, and arthropods.[29] Plant remains, including those that animals digested and excreted, contain organic compounds: sugars, starches, proteins, carbohydrates, lignins, waxes, resins, and organic acids. Decay in the soil begins with the decomposition of sugars and starches from carbohydrates, which decompose easily as detritivores initially invade the dead plant organs, while the remaining cellulose and lignin decompose more slowly.[30] Simple proteins, organic acids, starches, and sugars decompose rapidly, while crude proteins, fats, waxes, and resins remain relatively unchanged for longer periods of time.

Lignin, which is quickly transformed by white-rot fungi,[31] is one of the primary precursors of humus,[32] together with by-products of microbial[33] and animal[34] activity. The humus produced by humification is thus a mixture of compounds and complex biological chemicals of plant, animal, or microbial origin that has many functions and benefits in soil. Some judge earthworm humus (vermicompost) to be the optimal organic manure.[35]

Stability

Much of the humus in most soils has persisted for more than 100 years, rather than having been decomposed into CO2, and can be regarded as stable; this organic matter has been protected from decomposition by microbial or enzyme action because it is hidden (occluded) inside small aggregates of soil particles, or tightly sorbed or complexed to clays.[36] Most humus that is not protected in this way is decomposed within 10 years and can be regarded as less stable or more labile.

Stable humus contributes few plant-available nutrients in soil, but it helps maintain its physical structure.[37] A very stable form of humus is formed from the slow oxidation (redox) of soil carbon after the incorporation of finely powdered charcoal into the topsoil. This process is speculated to have been important in the formation of the unusually fertile Amazonian Spanish; Castilian: [[Terra preta|terra preta do Indio]].[38] However, recent work[39] suggests that complex soil organic molecules may be much less stable than previously thought: “the available evidence does not support the formation of large-molecular-size and persistent ‘humic substances’ in soils. Instead, soil organic matter is a continuum of progressively decomposing organic compounds.″

Horizons

Humus has a characteristic black or dark brown color and is organic due to an accumulation of organic carbon. Soil scientists use the capital letters O, A, B, C, and E to identify the master horizons, and lowercase letters for distinctions of these horizons. Most soils have three major horizons: the surface horizon (A), the subsoil (B), and the substratum (C). Some soils have an organic horizon (O) on the surface, but this horizon can also be buried. The master horizon (E) is used for subsurface horizons that have significantly lost minerals (eluviation). Bedrock, which is not soil, uses the letter R.

Benefits of soil organic matter and humus

The importance of chemically stable humus is thought by some to be the fertility it provides to soils in both a physical and chemical sense,[40] though some agricultural experts put a greater focus on other features of it, such as its ability to suppress disease.[41] It helps the soil retain moisture[42] by increasing microporosity[43] and encourages the formation of good soil structure.[44] [45] The incorporation of oxygen into large organic molecular assemblages generates many active, negatively charged sites that bind to positively charged ions (cations) of plant nutrients, making them more available to the plant by way of ion exchange.[46] Humus allows soil organisms to feed and reproduce and is often described as the "life-force" of the soil.[47] [48]

See also

External links

Notes and References

  1. Web site: Humus . 9 June 2024 . Dictionary.com Random House Dictionary Unabridged.
  2. Encyclopedia: Humus . Encyclopaedia Britannica Online . 2011 . 9 June 2024 .
  3. Chertov . Oleg G. . Komarov . Alexander S. . Crocker . Graham . Grace . Peter . Klir . Jan . Körschens . Martin . Poulton . Paul R. . Richter . Daniel . 1997 . Simulating trends of soil organic carbon in seven long-term experiments using the SOMM model of the humus types . Geoderma . 81 . 1–2 . 121–135 . 10.1016/S0016-7061(97)00085-2 . 1997Geode..81..121C . 9 June 2024 .
  4. Brêthes . Alain . Brun . Jean-Jacques . Jabiol . Bernard . Ponge . Jean-François . Toutain . François . 1995 . Classification of forest humus forms: a French proposal . Annales des Sciences Forestières . 52 . 6 . 535–46 . 10.1051/forest:19950602 . 16 June 2024 .
  5. Bernier . Nicolas . 1998 . Earthworm feeding activity and development of the humus profile . Biology and Fertility of Soils . 26 . 3 . 215–23 . 10.1007/s003740050370 . 16 June 2024 .
  6. Book: Weil . Ray R. . Brady . Nyle C. . The nature and properties of soils . 2016 . 15th . . Columbus, Ohio . en . 9781292162232 . 536 . 16 June 2024 .
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