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© IOIA
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Understanding Soil Health, Soil Tests, Crop Fertility Inputs and
Organic Fertility Management
Compiled by Steve Diver, Agriculture Specialist, Fayetteville, AR
For the International Organic Inspectors Association
IOIA Pre-Course
Soils Training
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Objectives
• a basic understanding of the soil ecosystem
• be able to recognize the key components of crop management that effect soil quality and health.
At the completion of the module, participants will have:
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Topics
• Soil Quality and Soil Health – Physical – Chemical – Biological
• Soil Organic Matter and Crop Management • Soil Tests and Fertility Management
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Soil Fertility Goals in Organic Farming
• Soil Quality & Soil Health
• Crop Fertility & Crop Vitality
• Food Quality & Nutritional Health
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Soil Health is the fitness or capacity of soils to support crop growth and maintain environmental quality.
Physical Chemical
Biological Soil Quality emerges from a .. … .. balance between
the three soil components.
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Three components of soil quality
• Physical (structural) – tilth, infiltration, porosity, bulk density,
aggregation, texture (mix of sand, silt and clay) • Chemical (mineral)
– nutrient content, salinity, pH, organic matter, clay, mineral content (parent material)
• Biological (flora and fauna) – living biota, biomass, biodiversity, biological
activity, biological control
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Sand Loamy Sand Sandy Loam Fine Sandy Loam Loam Silty Loam Silt Silty Clay Loam Clay Loam Clay
Coarse
to
Fine textured
soils
Soil texture relates to the size of the individual particles
– the texture designations range from
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Soil Texture Triangle What is the % mixture of a loam soil at this location?
Sand - 0.05 2.0mm
Silt - 0.002 0.05 mm
Clay - < 0.002 mm
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Soil structure • refers to the clumping together or “aggregation” of sand, silt, and clay particles into larger, secondary clusters. • these aggregates form roundish granules, cube-like blocks, plate-like
sheets, or prism-like rectangles.
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• determine pore space for air and water circulation, erosion resistance, ease of tillage, and root penetration.
• Texture is related to mineral components of the soil and does not change, but
• Soil structure can be improved or destroyed by choice and timing of farm practices.
Texture and Structure
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25 yrs of CT corn
20 yrs of bluegrass, then 5 yrs CT corn
Water stable aggregate test on rotation plots.
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25 yrs of conventional corn
20 yrs of bluegrass, then 5 yrs conventional corn
After adding water to soils from the rotation plots.
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Soil pH refers to its acidity or alkalinity, which is determined by the concentration of hydrogen (H+) and hydroxyl (OH-) ions in soil.
Soil pH determines the solubility and availability of essential nutrient elements to plants. Graphic: extension.missouri.edu/explore/agguides/soils/g09102.htm
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Effect of soil pH on plant nutrient availability
Graphic: www.ca.uky.edu/agc/pubs/agr/agr19/fff00009.gif
pH level
width of the bar
indicates availability
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pH - the negative log of
the Hydrogen Ion Concentration [H+]
Low pH or acidic - eg. 4.5 1/ [H+]4.5 or [H+]-4.5
Neutral pH of 7 balance of H+and OH-
High pH - alkaline eg. 8.5 [H+]-8.5
Liming ?? CaCO3 + H20 = Ca2+ + HCO3- + OH-
OH- + H+ = H2O Uses up the [H+] ions
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Acidifying and Liming materials approved for use in organic farming.
The OMRI Products List is a “key” guide to approved sources of crop fertility inputs and soil amendments.
OMRI Products List - www.omri.org
Acidifying • Elemental sulfur
Liming • Agricultural limestone • Dolomitic limestone
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Essential Elements for Plant Growth Major elements (required in large quantities) Nitrogen (N) Carbon (C) Phosphorus (P) Oxygen (O) Potassium (K)
Secondary elements (intermediate requirement)
Calcium (Ca) Magnesium (Mg) Sulfur (S)
Trace elements (needed in very small amounts) Copper (Cu) Iron (Fe) Zinc (Zn) Boron (B) Molybdenum (Mb) Manganese (Mn) Chlorine (Cl) Nickel (Ni)
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Cationic elements (+ positive charged ions)
Calcium (Ca) Copper (Cu) Magnesium (Mg) Iron (Fe) Potassium (K) Sodium (Na) Anionic elements (- negative charge on soil forms )
Nitrogen (N) Boron (B) Phosphorus (P) Selenium (Se) Sulfur (S) Chlorine (Cl)
Essential Elements for Plant Growth
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Cation exchange capacity (CEC) is a measure of the soil’s ability to store base cation nutrients (e.g., Ca, Mg, K, Na, trace elements).
CEC is affected by clay and organic matter (humus) content.
Base saturation is the percentage of soil CEC occupied by base cations.
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Table of Cation Exchange Capacities Don Schriefer - Agriculture in Transition
Sand + 2 -3 CEC
Silt = 5 - 7 CEC
Clay = up to 60 CEC
Humus = 250 CEC
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Soil Biota
Classification Body Width Examples
Microflora < 10 µm • bacteria • fungi • actinomycete • algae
Microfauna <100 µm • protozoa • nematode
Mesofauna 100 µm to 2 mm • mites • springtails
Macrofauna 2 mm to 20 mm • earthworms • millipedes
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Number of organisms in 1 cubic centimeter of agricultural soil: Bacteria 90,000,000 Actinomycetes 4,000,000 Fungi 200,000 Algae 30,000 Protozoa 5,000 Nematodes 30 Earthworm < 1
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Soil Life Under a Microscope, UV Light w/ Acridine Orange
Photo: Siegfried Luebke, CMC Group, Austria
Each glowing spot is a microbe
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Resources on Soil Biology & Microbial
Ecology
• Life in the Soil video • Soil Biology Primer
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Diagram: Elaine Ingham, Soil Foodweb, Inc.
Soil Food Web
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Soil Foodweb Influence on Crops Bacterial Dominated • Turfgrass • Vegetables • Row crops
Fungal Dominated • Fruit trees • Vineyards • Forests
Food Sources • Green plant material • High nitrogen • Easily decomposed
Food Sources • Brown plant material • High in cellulose, lignin
• Slow decomposition
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Diagram: Soil Biology Primer
Plants Determine Biology
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Bare Parent Material 100% bacterial
Cyanobacteria True Bacteria Protozoa Fungi Nematodes F:B =.01
“Weeds” -- High nitrates -- Lack of oxygen F:B =.1
Early Grasses -- Bromus -- Bermuda F:B =.3
Mid-grasses, vegetables F:B =.75
Late successional grasses & row crops F:B =1.1
Shrubs, vines, bushes F:B = 2 to 5 Deciduous trees
F:B = 5 to 100
Coniferous trees Old-growth forests F:B = 1000 to 10,000
Soil Food Web Structure Through Succession,
Increasing Productivity
Concept: Soil Foodweb, Inc.
F:B Fungal to Bacteria Ratio
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VAM Mycorrhizal Fungi This is a special kind of symbiosis between roots and fungi known as vesicular arbuscular mycorrhizae. The fungi live inside the plant, but they also send hyphae into the surrounding soil to gather water and nutrients for delivery to the plant. In exchange, the plant provides carbon to the fungi. The Rhizosphere The 3-dimensional zone at the interface between plant roots and bulk soil -- is home to a diverse microbial community that lives in association with plant roots. Plants slough-off tissue and excrete plant-manufactured substances like amino acids and sugars that feed and stimulate a microbial community that surrounds plant roots. In turn, these microbes make nutrients and microbial substances available to the plant, directly or indirectly. Rizobacteria that live in association with plant roots exude bacterial slimes and glues to benefit their own survival, but as a result these substances help release soil nutrients for plant uptake. These rhizobacteria function as biocontrol organisms by suppressing soil-borne plant pathogenic fungi that cause plant disease such as fusarium, phythium, and rhizoctonia. Mycorrhizal fungi that live in symbiotic association with plant roots obtain nutrients from several centimeters or even several meters further out into the bulk soil, thus extending the mycorrhizosphere.
The Root-Soil interface
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Soil Life Under a Microscope, VAM Mycorrhizal Fungi
Photo: Sara Wright, USDA
The yellow stain is a fungal glue (glomalin) that helps build soil structure and soil
organic matter.
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Rhizosphere Benefits for Microorganisms Root Excretions 1. Amino acids 2. Organic acids 3. Carbohydrates = Sugars 4. Nucleic acids 5. Growth factors 6. Sloughed-off tissue
Key: Food + Shelter + Energy for microbes
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Soil Organic Matter (SOM) is part of each component and binds and weaves them together.
Physical Chemical
Biological
… the binding thread Organic Matter
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Soil Composition
20-30% Water 45% Mineral
20-30% Air
50% Pore Space 50% Solids
5% Organic Matter
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Soil Organic Matter
Organic matter is 1-6% of total soil mass
living biomass 10-20%
active fraction 10-20%
humus 60-80%
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Pools of Soil Organic Matter Active or Labile SOM — fresh OM (litter, manure), living organisms, microbial biomass, partially stabilized OM; half-life in days to a few years
Slow or Intermediate SOM — stabilized OM derived from above; half-life of a few years to decades
Passive or Stable or Recalcitrant SOM — extremely recalcitrant molecules, humus; half- life of decades to centuries
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2% Organic Matter 4% Organic Matter
Effect of 20 years of conventional vs. organic management in the Rodale Farming Systems Trial
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Humus Management • Biological Farming Practices: Cover crops, rotations, compost,
tillage system, manures, microbials • Purpose: Soil organic matter
Food and Shelter for soil foodweb Clay-humus crumb
• “Feed the Soil” Number & Diversity of soil organisms
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Crop Rotations
Soil Depleting Row crops Soil Neutral Cereal Crops Soil Building Sod-forming grasses & legumes
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Crop Rotation: What does the inspector do?
• Is the grower following their plan?
• Is the same crop being repeated?
• Is there a balance of- Soil building crops Soil depleting crops Soil neutral crops?
• Do you see signs of the past year’s rotation (crop residues, etc)?
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Clover plant with
Rhizobium root nodules
Crimson Clover
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Crops vary based on:
• Regional climates:
- Cool season or warm season
• Type of plant
- Cereals, Legumes and Broadleaves
Cover Crops & Green Manures
Spader incorporating green manure
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Green Manures: What does the inspector look for?
• Is the seed for the green manure or cover crop organic?
• How much biomass is actually incorporated?
• How is it incorporated?
• Are their photos or records of dates of application?
• Did the green manure crop get planted and did it germinate?
• Inoculants?
Effects of OM additions Add
organic matter
Increase biological activity (& diversity?)
Decomposition
Nutrients released
Aggregation increased Pore
structure improved Humus formed
May reduce soil-borne disease
Improved tilth
HEALTHY PLANTS
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Composting a managed process of organic matter decomposition & humification C:N ratio Particle size
Mixing Porosity Temperature Moisture Aeration Microbes
Management Factors
“Humus is to OM,
as Bread is to Flour”
Compost Turner
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Material Carbon to Nitrogen Seaweed 20 (e.g., 20:1) Poultry Manure 5-15:1 Dairy Manure 5-25:1 Fall Leaves 30-80:1 Legume Hay 50:1 Corn Stalks 60:1 Grass Hay 80:1 Sawdust 200-700:1 Compost 10-30:1
Optimum OM digestion 10-30:1
C:N – Carbon:Nitrogen Ratio of Organic Materials
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Compost Rate of Application
Low 2-3 tons per acre
Regular 5 tons per acre
High 10-20 tons per acre
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Three Pillars of Organic Farming Fertility
• Compost – Compost, organic amendments, manures
• Cover Crops – Cover crops, green manures, living mulches
and intercrops, crop rotations, mulch
• Rock Minerals – Limestone, gypsum, rock phosphate,
activity, sul-po-mag, rock dusts
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Organic Soil Fertility
Main Concepts • Soil Test • Mineral Balancing & Remineralization • Humus Management & Soil Biology • Organic Fertilizers & Supplements
(Fertigation, Foliar Feeding, Biostimulats)
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Soil Test Report • pH • Buffer Index (lime rate) • OM (organic matter) • CEC – varies with soil type/texture • Base saturation – % for each cation • Nutrients:
- Major, - Secondary,
- Micronutrients • Nutrient Levels (depends on the crop)
- Low - Med - High - Excess
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Microbial - Humus • ABC Organics • BBC Labs • Microbial Matrix • Soil Foodweb, Inc. • Woods End
Minerals - Fertilizers • Agri-Energy Resources • Brookside Labs • Kinsey Ag Services • Midwestern Bio-Ag • Midwest Bio-Systems • Texas Soil & Plant Lab
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Three Pillars of Eco-Farming
• Mineralization – Soil tests, rock minerals, rock dusts, mineral
balancing, foliar fertilization, fertigation
• Humus Management – Composts, cover crops, crop rotations,
grazing, proper tillage, microbial inoculants
• Energetics (not included in this module)
– Photosynthesis, homeopathics, paramagnetism, sound
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Dr. William Albrecht Paths to Eco-Farming Fame 1. Univ. of MO
2. Brookside Labs 3. Acres USA 4. Base Saturation &
Mineral Balancing 5. Humus Management
1888-1974
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The Mineral Balancing Approach
• Balanced Fertilization provides Soil Structure and Soil Nutrients, supporting the work of Soil Microbes. • Ex. Calcium flocculates the soil, expands clay, increases porosity, facilitating oxygen transfer to roots. • A focus on interactions and Ratios Between Nutrients based on a soil test.
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The Albrecht Ratios
Ca++: 60-70%
Mg++: 10-20% H+: 10-15%
K+: 2-5%
Na+: 0.5-2%
Base Cation Saturation Ratio
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Remineralization Rock Minerals
Rock dusts (72 elements)
Sea solids and Seawater (52 elements)
Broad diversity + low concentration Secondary elements, Trace elements
Rare earth elements
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Rock Minerals examples of products used as soil amendments and fertilizer inputs
Rock phosphate
Sul-po-mag (K-Mag)
Limestone
Oyster shell
Greensand
Gypsum
Granite meal
Rock dusts
Granular humates
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Organic Fertilizers
Plant & Animal Byproducts Feather meal Fish meal Soybean meal Pelletized poultry litter Liquid Organic-Biological Fertilizers
Products & Suppliers:
OMRI Products List
ATTRA Organic Fertilizer List
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Seven Steps to Organic Soil Fertility
1. Cover crops & crop rotations 2. Compost 3. Rock minerals
4. Bagged organic fertilizer 5. Sidedress or fertigate
6. Foliar fertilization 7. Bioaugmentation with
biological inoculants and microbe teas
Fertilize the Crop
Supplemental Fertility & Biological Inoculation
Feed the Soil
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Landscape Overview - including fence rows
Crop Rotation - simple or complex
Soil Texture and Structure
Crop and Weed species - patterns
Nutrient Deficiency
Soil Test results
Biological activity
Evaluating Soil Fertility and Quality during a Farm Inspection
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Tatsoi
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Review ?’s 1. What is Soil Health? 2. What was the % sand, silt and clay for the loam soil? 3. What is the difference between soil texture and soil structure? 4. What can you observe about texture and structure as an inspector? 5. What is the optimum pH range for Phosphate availability? 6. List three trace elements. 7. Which will have a higher CEC – sand or clay? 8. What is an example of a microflora? – an example of mesofauna? 9. What is the Rhizosphere? What is a mycorrhizal fungi? 10. What are the three pools of Soil Organic Matter (SOM)? 11. Give a specific crop example for each of
– Soil depleting, Soil Neutral and Soil building. 12. What does C:N mean and what is a “good” number for compost? 13. What is a high rate of compost application? 14. What is “good” ratio for Ca:Mg? (based on Albrecht’s Theory) 15. What is Sul-po-mag?
Cont’d
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Humus
Structure
Texture
Soil fauna
Plant roots
Microbes
Colloids
pH
CEC
Anions & Cations
Aeration Drainage
Nutrients
Mycorrhizae
Biological
Physical Chemical
The Soil Ecosystem
16. Place the terms in one of the four areas
Tilth
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Soil Biology Primer - a question for each chapter
1. Soil Food Web - what’s missing?
2. Where do red wigglers fit in?
3. What causes the “Good Earth Smell”?
4. How do nitrogen fixing bacteria operate?
5. How can protozoa feed a crop with high N requirements?
6. What group of organisms play a significant role in P nutrition?
7. How can nematodes be both beneficial and pathogenic?
8. What is a more proper name for soil “Bugs”?
17. Complete the Pre-course Assignment and submit by deadline.
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