Soil organic matter (SOM) has been

Soil organic matter (SOM) has been called “the most complex and least understood component of soils” (22). The Soil Science Society of America defines SOM as the organic fraction of soil after removing undecayed plant and animal residues (27). However, organizations and individual researchers differ in their opinion about whether undecayed plant and animal tissues (e.g. stover, dead bugs, earthworms, etc.) should be included in the definition of SOM. In this chapter, we will adopt a broader definition of SOM proposed by Magdoff (1992), which consider SOM to be the diverse organic materials, such as living organisms, slightly altered plant and animal organic residues, and well-decomposed plant and animal tissues that vary considerably in their stability and susceptibility to further degradation. Simply put, soil organic matter is any soil material that comes from the tissues of organisms (plants, animals, or microorganisms) that are currently or were once living. Soil organic matter is rich in nutrients such as nitrogen (N), phosphorus (P), sulfur (S), and micronutrients, and is comprised of approximately 50% carbon (C).

Soil organic matter is complex because it is heterogeneous (non-uniform) and, due to the biological factors under which it was formed, does not have a defined chemical or physical structure. Soil organic matter is not distributed evenly throughout the soil and breaks down at various rates by multiple agents that are influenced by the unique environmental conditions in which they are found. Soil organic matter is present in all soils all over the world. Just as all life on Earth is dependent on the processes of microorganisms, SOM is transformed and degraded as a result of soil microorganisms.

All of the transformations discussed in this chapter – decomposition, mineralization, immobilization, denitrification, and nutrient cycling - are at least in part dependent on soil organisms. The same factors that regulate the SOM pool, especially precipitation and temperature, also control the activity and community composition of soil organisms. In fact, SOM and soil organisms are so interdependent that it is difficult to discuss one without the other. As the U.S. naturalist and explorer, John Muir, said, “When we try to pick out anything by itself, we find it is tied to everything else in the universe.” Soil organic matter and soil organisms are an excellent example and a testament to the wisdom of Muir’s teachings.

Soil organic matter accumulates to higher levels in cool and humid regions compared to warm and arid climates (20). In addition, SOM associated with different soil textures (sand, silt, and clay), will differ in susceptibility to decomposition. Many studies have shown that SOM associated with the sand-size fraction is more susceptible to decomposition, and thus a higher turnover, than the silt- or clay-size fractions (2, 11, 29).