Soil Fertility Management SBC YFC, 2013 Zach Wolf, Locusts on
Transcription
Soil Fertility Management SBC YFC, 2013 Zach Wolf, Locusts on
SOIL FE Soil Fertility Management SBC YFC, 2013 Zach Wolf, Locusts on Hudson [email protected] Overview Systems Approach Gathering Background Information Management Basics 2nd Tier Management Soil Tests Mineral Balance Managing Cover Crops Compost Qualitative Approaches The creation of our planet in 6 days, from David Brower Sunday • Earth is Born Monday • Cooling • Precipitation Tuesday • Bacteria Enter Wednesday • Earth Systems Evolve Thursday Friday • Self regulating planetary system Takeaway: 1) Earth systems and Biology co-evolved -Bacteria and Fungi are foundational for terrestrial organisms 2) Life transitioned to terrestrial ecosystems from marine ones -Distribution of mineral resources is limited by geology -Uptake through trophic levels in limited by soil biology 3) The novelty of our species, agriculture and science -Decision Making: Science, tradition, intuition Saturday • Plants, Animals, Fungi • Humans 11 sec before midnight • Agriculture 2/3 sec • Science 1/1000 sec Epistemology of Soil Fertility Linear Approach ¡ Mechanistic Experience/ Tradition Reductionist ¡ Parts ¡ Systems Approach Complex ¡ Interlinked through Feedback Mechanisms ¡ Holistic thinking ¡ Science/ Empiricism Intuition/ Sensing ÷ Need To Utilize All Three Aspects Where to Start? Web Soil Survey, http://websoilsurvey.sc.egov.usda.gov/ App/HomePage.htm Find and Research Soil Type Formation/ Regional Geology Landuse History ¡ Potential Contamination Type and Quality of Vegetation Water Holding Capacity/Drainage Crop Performance ¡ ¡ ¡ ¡ ¡ Yield Pest/Disease Pressure Growth Rate Growth Rate Through Cool Weather Deficiency Symptoms Approach Basics ¡ Air ¡ Water ¡ Temperature ¡ pH Second Stage ¡ Soil Minerals ¡ Organic Matter ¡ Cropping System (Finding Symbiosis) ¡ Tillage Soil pH Minerals and Soil Testing Levels of Availability ¡ Mineral Reserve ¡ Colloid ¡ Solution ¡ Tissue CEC…in context BSR…In context ¡ Ca:Mg:K:Na = 68:12:5:3 P=K S= ½ P Mn = 1/3 Fe Zn = 1/10 P Cu = ½ Zn B = 1/1000 Ca Trace minerals <1-2 ppm Soil Test Analysis cec Cation lbs/acre/1cec % saturation, optimal lbs optimal 10 Ca 400 0.68 2720 10 Mg 240 0.12 288 10 K 780 0.035 273 10 Na 460 0.025 115 10 H 20 0.1 20 Anion 0.96 P equal to K (Phosphate:Potash=2:1) 273 S 1/2 p (<600 -1200lbs) 136.5 Cl 1x, 2x Na 115 Minor nutrients Fe 1/3 - 1/2 P (200-600lbs) 91 Mn 1/3 -1/2 Fe 30.333333 Zn 1/10 P (<100lbs) 27.3 Cu 1/2 Zn 13.65 B 1/1000 Ca (<8lbs) 2.72 Trace nutrients Cr trace, <2-4lbs Co trace, <2-4lbs I trace, <2-4lbs Mo trace, <2-4lbs Se trace, <2-4lbs Sn trace, <2-4lbs V trace, <2-4lbs Ni trace, <2-4lbs Fe trace, <2-4lbs Si trace, <2-4lbs Field Old Post South Nutrient (lbs/ Crop Test Compost (10 acre) Demand Results Needed ton/acre) N P K Ca Mg S Zn Cu B 130 54 218 78 21 29 6.1 2.5 1.4 160.8 62 -144 -246 -47 -97 2.88 1.78 0.52 -30.8 -8 361.76 324 68 126 3.22 0.72 0.88 80 26 50 150 46 16 1 0.5 0.16 Monitor Soil Testing Over Time 2500 2000 Lbs./Acre 1500 1000 500 Fall13' Summer13' Spring13' Summer12' Spring12' 0 Ca Mg Nutrient K Na S P ENR Plant and Soil = One System Soil is the digestive system for the plant Plant acts as a solar receptor for soil biology 20-80% of photosynthates delivered to soil system through exudates Plant as important source of C for soil food web Soil food web facilitates the movement of minerals to the plant Mycorrhizal Fungi Symbiosis Reduce Tillage Limit P-inputs Inoculate Soil Cover Crops Avoid bare fallow Rotations ¡ Based on patterns of succession ¡ Applying Ecological Theory 1) Functional Diversity ¡ ¡ ¡ Enhances Ecosystem Functions * Functional Traits, not simply species or varietal diversity ÷ Rooting depth, root mass, diseas/pest resistance, etc. Diversity Measured over time 2) Disturbance Regimes ¡ Tillage ÷ Frequency ÷ Intensity 3) Successional Pattern Rotate crops in sequence to build fungal symbiosis and complexity • Year 1 Brassicaceae, Chenopodiaceae Compositae, Apiaceae, Cucurbitaceae • Year 2 Poaceae, Solanaceae, Allium Successional Sequence, from Soil Food Web Early Bare Parent Material Bacteria Early Annuals Mid-grass, veggies Pasture, Row Crops Bushes Late Deciduous Forest Old-growth Forest Fungi • Year 3 Cover Crops Alleys Reduced Tillage baby greens carrot -The cycles in nature, that includes decay and decomposition of organic matte beans corn, sweet -The creation and maintenance of soils. cucumbers garlic -The nutritional value of cultivated plants. radish lettuce spinach melons According to Elaine Ingham when virgin prairie land, the archetype for a healthy soil onion is plowed, no pesticides or squashes fertilizers are needed for the first 5 to 15 years. I hav peppers experience with virgin land but we all recognize that disease-suppressive bact protozoa, and nematodes can protect plants from infection, whiletomatoes the natural nutrient nitrogen retention provides the crops with their nutritional needs. By exposing the Figure 1.the Timing ofofnitrogen mineralization elements, we diminish number beneficial organisms and from burn up the organic ma no new organic matter is returned, we notcrop onlyresidue, stop feeding the beneficial organism soil organic matter, cover and organic deteriorate thefertilizer characteristics of the This process is not any different from in relation to soil. crop nitrogen uptake. pasture land. Overgrazing reduces diversity and population of grasses when and cloth pastures just as working the land reduces the microbial population of the soil. A r Crop Demand 20:1 (e.g these organisms eventually results in disease problems. The challenge of organic f Fertilizer maintain a balance between what is taken from the land and what is returnedmustard to the soilredu in o shortcuts like the use of artificialmineralization fertilizer or pesticides that cause even greater crop organism. According toCover Elaine, one teaspoon of healthy soil should containhigh about nit Cover crop incorporation mineralization bacteria, three miles of mycelia, 10,000 protozoa and 20 to 30 beneficial nematodes. tition fo Build SOM Over Multiple Year Cover Crops Time Nutrient Mineralization with Peak Crop Demand Residue Incorporation Soil Contact ¡ Depth ¡ Particle Size ¡ Moisture ¡ Temperature ¡ Rate or N mineralization or crop N uptake Managing Crop Residues vegetab Recognizing the processes that happen in the soil can help make a contribution crops mw Soil organic matter mineralization healthy ecosystem. Nutrients removed from the field have to be returned to close the cereals type of nurturing is not unlike any other type of husbandry. We need to distinguish th 0 4 8 the This soil requirements of the different creatures that live below the surface of the soil. Weeks rally similar to putting cows on lush pasture. A good farmer feeds all its animals even ni th can only be seen with a microscope. availab residue C:N rat 68 Cover Crops matter, Cropland Sod Cropland tility an Cover crops fix and trap nutrients, add organic matter 64 A longe to soils, and reduce nitrate leaching, nutrient runoff, fore rec 60 and soil erosion. In California, cover crops are widely pattern used in organic farming systems because the climate is 56 duction mild enough to support growth during the fall, winter, Less Total Organic Matter and early spring in most crop production areas. 54 cover c Nonleguminous cover crops, such as grasses and 50 quent c Brassica species, are preferred in situations where nutriin resis ent availability 5is high where cover5 crops 10 in the 15 fall and 20 25 10 unavail Based onnitrate bemesting andand meststoffen by ir W. T. Rinsema that et al Time in Years can trap phosphate would otherwise readily be lost by leaching or runoff. Nonlegumes also tend to dues, Spreading compost hastolerant a different effect temperatures on soil life andthan soil legumes. quality compared to sph be more of cooler manure or plowing under manure. Compost is a when finished product plant-a with litt Legumes fix green atmospheric nitrogen, at least con- NUTRIENT SOURCES organic matter in tons/acre Making Compost Nutrient Capture Handle/Stockpile Materials Building the Pile, C/N Ratio (20-40:1) Cover Monitor Turn Cure The Composting Process Phase 1 Breakdown Phase 2 Buildup Speed and Temp. More N and C conserved Compost Varies in: ¡ ¡ ¡ % OM Mineral Profile Mineral Release Stored in Humic Molecules Minerals stored as Humates Antigo silt loam, contains 1 to 4% organic matter. Crop cultivation, harvesting, erosion, and natural decomposition gradually reduce the amount of organic matter in soils. However, you can maintain and even increase your soil's current organic matter level through proper management. Compost Application Rates Build Stable OM Microbial Inoculant Water and Nutrient Holding Improve Soil Structure Pools of soil organic matter based on decomposition level Not all soil organic matter is created equal.South Fruit and To Compost Analysis Soil Analysis Garden vegetable wastes are easily degraded because they contain mostly simple carbohydrates (sugars and Nutrient lbs/c.yrd. lbs/ton lbs/acre tons to apply starches). In contrast, leaves, stems, nutshells, bark and Figu N 5.2 8.684 (acti trees decompose more slowly because they contain func P 1.6 2.672 -138 -51 funct cellulose, hemicellulose and lignin. The ease with K 3.3 5.511 140 25 which compounds degrade is determined by the Ca 9.1 15.197 408 26 Well complexity of the carbon compounds and generally Mg 2.8 4.676 33 7 as m follows the order: carbohydrates > hemicellulose > Na 0.4 0.668 38 56 activ cellulose = chitin > lignin. such S B Cu Fe Al Mn Zn 1 1.67 78 46 0.01 0.0167 1.2 71 In contrast to fresh plant residues, composted organic171 0.03 0.0501 8.6 materials decompose slowly when added to soil 8 13.36 -433 -32 because they have already undergone a significant 5.6 9.352 0 amount 0.34 of decomposition during the composting 0.5678 -45 -79 process (Fig. 0.06 2). 0.1002 6.4 63 0.0 N P K Ca Mg S Cu Mn Zn Compost Analysis (10 tons) Tons/acre OM 50.0 10 Cover Crop Ta qu 6 3 0 6 How soi Compost 150.0 Compost Analysis (10 tons) Ave. Crop Removal prev Soil links a so func drain pollu 200.0 100.0 De 12 Months after soil incorporation Figure 2. Composted organic materials decompose more slowly than fresh organic matter because they have already undergone a significant amount of decomposition. 1. mi ca 2. ag 3. inf 4. ab Summary of Management Principles Apply soil amendments when needed (tight nutrient budgeting) Use tillage appropriately for Incorporation ¡ Soil aeration ¡ Use inoculants Build soil with intensive cover crops Minimize bare soil or times with no carbon input Capture farm nutrients and generate humus Monitor, Test, Observe, and Sense… Chromotography Understanding through Qualitative observations Soil Food Web Testing Bacteria Fungi Protozoa Nematodes Mycorrhizae Nitrogen cycling Building Intuition Making time to experience, observe and be present Generating Trust Experimenting Reading and Research Connecting with other Farmers and Land Managers Channel Inspiration The Farm can become a “Living Lab” Books From the Soil Up, Schiefer Soil Chemistry 3rd Edition, Bohn The Nature and Properties of Soil, Brady Healthy Crops, Chaboussou The Ideal Soil, Astera Mineral Nutrition of Higher Plants 2nd Edition, Marschner Building Better Soils, Magdoff Soil Science Simplified, Kohnke Amendment/Compost Sources Lanchaster ag. North Country Organics (distributed through Compost Werks) Midwestern Bio ag. Fertrell Hudson Valley Organics Stone Barns Center Vermont Compost Company Thank You!