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SFI Approach

INTRO

Soil Foodweb Technology is based on years of research by many different people. All science builds on previous science, the efforts of scientists to understand why the world works the way it does. Science is an on-going process of quantitative assessment and understanding of mechanisms on which life is based. In the following information, we have provided a number of links to pages that also share in this voyage of discovery. There is much yet to discover. Please work with us to find the sustainable approach...

Soil Foodweb Approach

Part 1: Understanding the Soil Foodweb

Part 2: Understanding Compost Biology

  1. The SFI Compost Approach
  2. Food Web Diagram
  3. How to Tell Good Compost - Compost Standards

Part 3: Understanding Compost Tea

The SFI Compost Approach

All of the information in this section applies to compost made by thermal composting, by worm-driven processes (cold-composting), or by static composting. Differences in microbiology between these different ways of reaching the same end-product, as far as the plant is concerned, are in The Biology of Compost book, written by Dr. Elaine Ingham. Please see our product page for information about the book.

Compost is used for one of the following reasons, generally:

  1. To add organisms to the soil. This is not just bacteria, but fungi, protozoa, nematodes and often microarthropods. Compost serves as an inoculum of all these organisms, if the compost is made correctly.
  2. To add foods to feed bacteria, fungi, protozoa , nematodes and microarthropods.
  3. To add structure to the soil. Many composts contain physical structure components like kor (cocnut fiber), clay, fiber, and chunks of wood. These impart physical structure that allows oxygen to move through the material. It is very important to maintain these air passageways into the compost.

Many people think of compost as a source of enzymes, hormones, and plant growth promoting materials. But while those materials are important, they do not last long in soil, or in compost.

What is the “life-expectancy” of enzymes, hormones and other good-food resources for bacteria or fungi to consume in compost, or soil? Unless the organic matter is absorbed on the surface of clay or organic matter – and thus protected from uptake by the plant or more difficult for the bacteria or fungi to access – these nutrient-rich compounds will be consumed by something within minutes. One more caveat - normal biology has to be present. If the enzymes has been separated into sterile conditions, then of course it won’t be used as food. But as soon as any protein or sugar (all enzymes are proteins, all hormones contain sugars and/or protein in their structure) is put into a habitat where bacteria or fungi are actively growing, that food is going to be gone.

What makes enzymes, hormones, and plant-growth-promoting materials? The bacteria, fungi, protozoa, nematodes and microarthropods. So, really, what you want to be adding is the biology, because they will make more of the enzyme you want. Or the hormone. Make certain that the compost contains the right set of bacteria, fungi, protozoa and nematodes so the process you want will occur. If you buy really good compost, the microarthropods will be present too.

There is a “best food web” for each combination of crop type, climate, region, soil type, amount of organic matter and water supply. The ideal food web balance for row crops in Arizona is different than the ideal balance for fruit trees or grapes in California (see SFI Approach, Succession and the Soil Foodweb) LINK

So, make or buy compost that will make a habitat appropriate for your plant to grow. In general – and this is a huge generalization – annuals need bacterial-dominated soil to maintain pH, form of N, soil structure, and nutrient cycling correct for those plants. Perennials need fungal-dominated soil to maintain pH, form of N, soil structure and nutrient cycling correct for the long-lived plants. Exceptions? Sure. But in general, this holds true everywhere we are looking at this all over the world.

Now, if growing plants in soils where the biology isn’t right, you can get plant growth, by using the toxic chemicals to try to overcome the diseases that will attack the stressed plants, by using chemical salt inputs to try to feed the plants the inorganic nutrients they need. But the plant is not healthy, it is stressed, and the food it makes is not the best for human consumption.

Can we increase production of plant material in un-healthy systems? Sure. But at what cost to water quality? What cost to human nutrition? To the quality of our lives? The long-term impacts are going to be staggering.

So, when trying to decide what compost is needed, and when trying to determine what compost to buy, understand your purpose in using compost very clearly.

The tests you need then should be come clear.

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Food Web Diagram and Explanation

Compost Food Web box diagram

Compost organisms perform a number of important processes during composting. But their importance doesn’t stop there – those organisms survive and live in soil, on leaf surfaces, and around roots, leaves, stems, blossoms, etc. They can create a protective layer on leaves, stems, blossoms, fruit and any above-ground as well as below ground surface.

Bacteria and fungi – the WHOLE diversity of these organisms, not just one or five or 20 species, but the whole 25,000 or more that could potentially be present in good compost - retain nutrients in the compost, and ultimately, in your soil too. Or on your leaf surfaces, if you could somehow get compost to stick to leaves. Except, that is possible, if you turn the compost into compost tea – see the sections on compost tea!

Protozoa and nematodes – the good guy nematodes only please! – then mineralize nutrients from the retained nutrients held by the bacteria and fungi. In compost, these mineralized nutrients serve to help other organisms grow and utilize the carbons sources in the organic matter put in to the compost pile.

Bacteria and fungi build micro- and macro-aggregates in the compost as well, and the protozoa and nematodes help build the larger pores in compost, so within a week or so, if you have the right biology in the compost, air passageways and water-infiltration-hallways have been built by the organisms. Turning becomes less and less critical as the biology grows and forms structure for you.

If the compost pile can be left alone, and you have a good set of local microarthropods or earthworms that can move into the pile, then they will move into the pile and set up housekeeping too, stimulating the growth of the fungi, and building structure, improving aeration, aggregation, and taking care of any pathogens in the pile.

Vermicompost, or composting using worms instead of heat, shifts the species of bacteria, fungi, protozoa and nematodes as compared to thermal composting, and generally, worm-compost contains some extremely beneficial bacterial and fungal species that are in lower densities in thermal compost. The worms quite clearly enhance certain beneficial bacterial and fungal species. Worm compost is also generally much higher in protozoa, and often have quite complex aggregation patterns that result in a great range of food resources for the beneficial species in the compost.

The dynamic, living system in compost is very influenced by the foods you choose to put into the compost pile, by the biology on the organic matter going into your pile, and by rain, wind, heat, sunlight, and pollution that occurs while you are composting. Only if some disturbance harms the community of beneficial organisms in compost will disease be able to get foothold in the pile.

Understanding compost health requires knowing:

  1. what organisms should be present (community analysis),
  2. how many are present (total biomass of each group), and
  3. how many should be functioning (active biomass).

If anything has been harmed or reduced, or put out-of-balance during the composting process, you either have to start over again, or use a good compost tea to replenish the lost organisms.

Plants depend on beneficial microorganisms in the following ways:

  1. to protect them from pathogens,
  2. to retain nutrients in the soil so they do not leach from the root zone,
  3. to cycle nutrients into plant available forms (both predator-prey and mycorrhizal fungi function to these ends),
  4. to improve uptake of soil or foliar nutrients,
  5. to break down pollutants in the soil, on on aboveground plant surfaces or around the roots, and
  6. to build the air passageways, hallways, lving rooms, dining rooms, kitcnes, and swimming pools that allow air and water to move into the soil, and to be retained so roots can grow as deep into the soil as physiologically possible, and obtain water and nutrients all year long, regardless of drought.

If the organisms that perform these benefits are missing, they need to be replaced.

The food web in compost will not contain many of the higher level predators if the compost is turned often. But as time from last turn increases, and there is a source of the beneficial organisms to colonize the pile, the higher trophic level, predator organisms will colonize, survie and grow in the compost pile.

Pests in the compost pile need to be discouraged by the habitat built by the biology in the pile. A good compost should be resistant to any diseases moving into the pile, because the beneficials have fully occupied the pile. If something happens to favor the growth of pests, however, then diseases or pests may be selected, and take over the pile. Biology is always a process, never totally stable, never something you can just ignore.

Factors important in making compost:

The Starting Materials

Do you want the final compost to be bacterial, or fungal? Are you making thermal compost, or worm compost? Do you want to be finished in 6 weeks, or can you take more time?

You have to know these answers in order to select for the right kinds of starting materials. We can reach the same end-point – from the plant’s point of view – with any composting approach you want to take. From the point-of-view of the microbiology of the compost, each stick of wood, each leaf of each plant, each different kind of material you add in will change the species composition of the compost pile.

Diversity

From a human point of view, what level of resolution do we need to know?

We don’t need to know the precise names of all the organisms in the compost pile. Just like a human city, we don’t need to know the first and last names of each human in the city in order to be able to know if that city is a good place to live. Is it functioning properly?

We need to know if the diversity of bacteria is adequate, if there is enough bacterial activity so the functions of nutrient retention, disease-competition and microaggregate building are going to be performed adequately. Fungal diversity needs to be adequate too, so the functions of the fungi are carried out properly. So, we need to know active bacterial biomass, total bacterial biomass, active fungal biomass, and total fungal biomass in order to know if the compost is good for the plant we want to grow.

Activity

There are minimal levels of activity and total bacterial biomass, active and total fungal biomass that are needed regardless of plant type, and then we can change whether the compost will be more fungal or more bacterial, by adding in foods that shift fungal or bacterial growth, just as you put the compost out on the soil, or use it to make compost tea.

To heat or not-to-heat?

Heat in a thermal pile is the result of the growth of bacteria and fungi. The more rapidly bacteria and fungi grow, the faster the pile will generate heat. You have to have the right ratios of carbon and nitrogen, but all the rest of the nutrients must be adequate so these other nutrients are not limiting either. But generally, in plant material, all the other nutrients are in good amount, it is the C:N ratio that will determine how hot the pile will get.

These ratios, the proper way to alter the relative amounts of high nitrogen plant material to not-high nitrogen plant material to low nitrogen plant material is explained in the compost book.

The compost biology book also explains why with back-yard composting, the ratio of high N to not-high N to low N has to be different. With back-yard composting, we only have to turn once after the pile has gotten started, but with commercial composting, we have to turn more often.

The need for proper “chunky” material is also explained, as well as how to aerate the pile. Again, back-yard is quite different from commercial conditions.

There are many factors that can be worked with to make compost be what your plants need, and that will help you reduce, and most likely end entirely, your reliance on toxic chemicals in order to raise high yields of fruits and vegetables. Let us help you do that. Check out Teaming with Microbes for more information.

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How to Tell Good Compost - Compost Standards

Use the chart below(in development) to determine whether the compost you have can successfully transfer the minimum organism biomass for each of the different groups in the soil or compost food web to the soil.

Your soil needs the right biology in order to grow the plants you want, without the use of toxic chemicals. If your soil, potting mix, hydroponics medium, or compost lacks the minimum set of organisms, steps need to be taken to re-establish the right set of organisms.

First, you need to establish what biology is present in your soil, and what biology is in the compost or compost tea you will add to the soil. The fastest way to do this is to send in a sample of both the soil and compost or compost tea to determine the biology present.

Second, you need to determine where you need to be adding the compost or tea to the soil. Directly on the surface may mean a time period while the organisms move into the soil. Typically, bacteria and fungi need to be carried deeper into the soil by protozoa, nematodes, earthworms, and/or microarthropods. If you don’t have these larger predator organisms, then you have to physically move the organisms into the soil, by tillage (which will harm the predators an fungi), or by coring and re-filling the core holes with compost, or a mix of compost and sand.

The alternative to using microbial assays to fix your soil is use of cover crops and organic matter additions to try to move the biology in the right direction. If you have time and an observant eye, you can use plant responses as an indicator that the additions you made last year, or earlier in this year are moving the biology in the correct direction. This approach takes time and patience, and may result in the loss of a crop or two before you learn to recognize what the plants are trying to tell you about the management you perform.

The compost you use needs to have the right biology. That’s the answer, the right biology.

With the right set of organisms, disease organisms will be prevented from having unrestricted access to your plants. Nutrients will be retained in your soil, instead of ending up in your drinking water, surface waters and the ocean, killing the organisms there as the result of toxic accumulations of nutrients. Nutrients will be cycled into the proper forms at the proper pH, at the proper time, for the growth requirements of your desired plant, if the right biology is present. Soil structure will be improved, and typically, pesticide use falls to practically nil when the biology sets the conditions in your soil to select for the growth of your desired plant. Water use decreases, because you retain water in the soil instead of having it wash right through the soil. Organic matter is important, but the biology on that organic matter are the real keys. Together, the right biology and the foods to feed them will allow the plant you want to grow to the exclusion of other plants.

Desired levels of organisms (direct microscopy) in aerobic compost or vermicompost (measured in fresh weight compost, but expressed per gram dry weight of compost).

In the past, these values were considered to change slightly through the year, but as we realized that good compost has to reach temperature regardless of ambient temperatures. That means you can compost in Minnesota in the middle of the winter – you just have to have the starting materials at 60 to 65 or higher for the first three days to get things going.

Bacteria

Fungi

Protozoa

Nematodes

Mature Compost

Habitat requirements for beneficial bacteria, fungi required to obtain thermal death of pests and pathogens

Thermal Compost

Vermi-compost

• For vermicompost: At least 75 to 80% of the material in the worm bin must actually pass through the worm digestive system. No weed seed can be added or materials must be pre-composted

Testing Requirements

Thermal compost

Vermi-compost

Sampling requirements for healthy foodweb assessment

Thermal compost

Vermi-compost

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