Fig 1: Relationship between topsoil organic materials and corn grain yield. Source: adapted from Fernández et al, 2012.
What are organic materials?
Organic materials are the fraction of the soil that includes approximately 5% of living organisms, 10% crop residues, 33-50% decomposing O.M. (the active fraction) and 33-50% stable O.M. (humus) by weight (USDA-NRCS, 2014). The active fraction of O.M. readily changes mass and form as it decomposes; thus, it is unstable in the soil and is most affected by management practices such as tillage, cover crops, and crop rotations (Carter, 2002). The rapid turnover of the active fraction can contribute to nutrient release for crops. Humus on the other hand, is organic material that has been converted by microorganisms to a resistant state of decomposition. Humus improves soil fertility by acting as a reservoir for nutrients, increasing the water holding capacity of the soil, improving soil structure and friability, and providing a source of energy for living soil organisms.
The Benefits of Organic Materials
Increasing levels of O.M. improve the physical, chemical, and biological functions of the soil. The benefits of O.M. are summarized into the following five functions:
1. Biological Function
There are many benefits to O.M., most of which begin with enhancing the biological diversity and activity in the soil. As O.M. increases, microbial activity tends to increase. Organic materials consist of 58% carbon, which is required in combination with other nutrients for microbial activity. Microorganisms excrete compounds that also act as a binding agent for soil particles, which can increase aggregate stability, water infiltration, and water holding capacity.
2. Nutrient Supply
Organic materials are a valuable nutrient source for plants and living organisms. As microorganisms increase their activity during warmer weather that occurs predominantly in the spring and summer, greater amounts of nutrients are cycled from organic forms into those that are inorganic and plant available. For every % of O.M. in the top 6-inches of a medium-textured soil (silt and loam soils), approximately 10-20 lbs. of nitrogen, 1-2 lbs. of phosphorus, and 0.4-0.8 lbs. of sulfur are released per acre annually (USDA-NRCS, 2014). In addition, O.M. particles contain sites of negative charges (i.e., cation exchange capacity [CEC]) that attract and hold positively charged ions such as calcium, potassium, magnesium, and ammonium-nitrogen.
3. Soil Structure
Organic materials cause soil particles to bind and form stable soil aggregates, which improves soil structure. With better soil structure, water infiltration through the soil increases and improves the soil’s ability to absorb and hold water as well as reduces the potential for surface crusting of the soil.
4. Water Holding Capacity
Soils with higher O.M. can infiltrate and store water at greater capacities. Organic materials behave similar to a sponge, with the ability to absorb and hold up to 90 percent of its weight in water. A great advantage of the water-holding capacity of O.M. is that it will release most of the water that it absorbs. Figure 2 shows the increase in plant available water with higher O.M. content across three different soils. Increasing O.M. one percent in the topsoil decreases the bulk density and increases the available water capacity by approximately 0.2-0.3 inches, which can be extremely valuable to help plants manage water through periods of moisture deficits.
Fig 2: Relationship between organic materials (%) and available water capacity (inches) in the top six inches of three different soils. Source: Adapted from data by Hudson, 1994.
5. Erosion Control
Greater aggregate stability is often the result of soils with more O.M., which can increase water infiltration rates and result in reduced potential for water, soil, and nutrients to erode. Data used in the universal soil loss equation indicate that increasing soil O.M. from 1 to 3% can reduce erosion 20 to 33% because of increased water infiltration and stable soil aggregate formation.
Management Practices to Increase Soil Organic Materials
Several factors such as climate, soil type, crop grown, and specific management practices can each influence the amount of soil O.M. regionally or in specific fields; therefore, local conditions should be used as benchmarks for comparison when implementing practices to increase soil O.M. (Figure 3, STS).
Soils that have greater O.M., such as those originally developed in prairies, annually cycled residues to the soil whereas forest soils with lower O.M. took longer to cycle the woody material back to the soil. Building soil O.M. is a slow process that takes years or decades as it requires the addition of substantial plant biomass and protection from loss over time. Listed below are three management strategies to build and maintain soil O.M.:
1. Minimize tillage or adopt no-till: slows soil organic residue decomposition and gives greater protection to the soil from erosion.
2. Add crop residues by including cover crops, organic materials (e.g., residues, manure, etc.), or growing a high biomass/yielding crop rotation. Crop residues help protect the soil surface from raindrop impact and erosion and add carbon back to the soil.
3. Soil test and apply advanced crop nutrition: identify and correct yield-limiting factors to encourage greater growth of crops that can be returned to the soil. Adding crop residues that help build or maintain O.M and including innovative products like Sus-Terra fertilizer that contain O.M. and other potentially limiting essential crop nutrients can create more productive and sustainable cropping systems.