Production of Biofuels Feedstock on Agriculture Land and Grasslands W. W. Wilhelm 1, Gary Varvel 1, Rob Mitchell 2, and Brian Wienhold 1 1 Agroecosystem Management Research Unit 2 Grain, Forage, and Bioenergy Research Unit USDA-ARS, Lincoln, Nebraska Conference on the Ecological Dimensions of Biofuels Ronald Reagan Building and International Trade Center Washington, DC, March 10, 2008
Important World Issues Reliance on fossil fuels. Increasing levels of greenhouse gases. Increasing human population requiring an increase in the production of food and fiber.
Expectations for Agriculture Provide traditional outputs for an increasing world population Food Feed Fiber Environmental services Control erosion Sequester C Habitat Water quality Renewable energy feedstock* 998 million tons (428 million ton from crop residues) * Perlack et al., 2005; http://bioenergy.ornl.gov
How will agriculture meet these demands? Goal (billion gal ethanol) 90 75 60 45 30 15 0 October 2007 capacity* (6.9 billion gal) 20 in 10 25 x 25 Energy Policy Act 2005 2015 2025 2035 Year EISA 30 x 30 Gap for cellulosic ethanol to fill Ethanol from corn (NCGA**) *RFA, http://www.ethanolrfa.org/industry/statistics/#c **NCGA, http://www.ncga.com/ethanol/pdfs/2007/howmuchethanolcancomefromcorn0207.pdf
Billion Ton Report (1.366 billion tons/year) Crop residues 428 Perennial energy crops 377 Grain 87 Ag wastes 87 Forestry 368 Estimated biomass (million tons/year) contribution by 2030 Perlack et al., 2005; http://bioenergy.ornl.gov
What is ONE BILLION tons? Agricultural land (cropland plus hay and pasture) 5 ton ac -1 200 million acres 56% of North Central Region agricultural land All of the agricultural land in Iowa, Illinois, Nebraska, Minnesota, Indiana, and South Dakota (Total = 195.5 million acres)
Energy Supply is Not the Problem Collecting and delivering energy in a usable format is the issue.
Transportation Fuel is the Issue Renewable Reduced greenhouse gas emissions Domestic supply Energy security Economy Rural development Balance of trade Fuel conservation must be addressed Demand for fuel continues to increase
Sustainability is Imperative Meet current needs in a manner that does not jeopardize the capacity of future generations to have their needs met.
How is Sustainability Measured?
Soil Components and Sustainability Water 25% Air 25% Organic matter 5% Roots 0.5% Mineral 45% Humus 4.0% Organisms 0.5% SOC - small fraction with large function aggregation, aggregate stability, infiltration, water holding capacity, bulk density, soil tilth, nutrient availability & cycling, buffering capacity, etc. SOC is the best available proxy for soil quality & sustainability
C Cycle in an Agroecosystem Light Ecosystem boundary CO 2 Reduced C Products Grain Forage Stover Soil organic carbon SOC = Σ (Inputs Outputs) (after Liang and McConkey, 2000) C Inputs must equal or exceed C Outputs or SOC declines
Meeting Expectations Sustainably Modern agriculture Soil carbon Pre-cultivation steady-state Management change Time SOC = Σ (inputs outputs)
Meeting Expectations Sustainably Modern agriculture Stover harvest Soil carbon Pre-cultivation steady-state Management change Time SOC = Σ (inputs outputs)
Meeting Expectations Sustainably Modern agriculture Stover harvest Soil carbon Pre-cultivation steady-state Management change + No tillage? Time SOC = Σ (inputs outputs)
Meeting Expectations Sustainably Modern agriculture Stover harvest Soil carbon Pre-cultivation steady-state Management change + Cover crops Green manure Increased efficiencies Innovative technologies + No tillage? Time SOC = Σ (inputs outputs)
SOC & Erosion Limit Crop Biomass Removal Common assumption: system is sustainable if retained crop residue reduces erosion losses to less than T 8 Stover to retain (ton ac -1 ) 6 4 2 0 3.38 Soil organic carbon Water erosion Wind erosion 1.39 0.77 2.34 0.29 0.06 5.58 3.56 1.22 3.52 0.43 0.15 Moldboard plow No or conservation tillage Moldboard plow No or conservation tillage Continuous corn Corn-soybean Wilhelm et al., 2007. Agron. J. 99:1665-1667.
Biomass Sources From Agriculture Grain Crop residue Dedicated energy crops
Grain Advantages Current feedstock (largely corn) Production, storage, transport, marketing, and conversion technology and expertise exist Liabilities High market price increasing production area Land use shift-marginal land returned to production Less rotations, more monoculture, less landscape and species diversity Demand met by increased yield per unit land Improved genetics, improved practices
Grain Caveats Technologies exist to improve production efficiencies (improve yield without aggregating environmental concerns) Under-used practices Cover crops, green manure crops Innovative technologies
Cover Crop in Annual Cropping System Missed opportunities for resource assimilation and dry matter production Dry matter production or resource loss (mass / time) Spring Annual grain crop Summer Autumn Winter cover crop Winter Resource losses (nutrient leaching, erosion) after A.H. Heggenstaller
Crop Residues Advantages Production technology and expertise exist Residue yield increases with grain yield Harvest index Cultural practices Breeding emphasis shift to biomass Liabilities/Limitations Currently important for: Erosion control SOC Livestock feed Increasing with supply of DDGS
Dedicated Energy Crops Annuals (triticale, sudangrass,, tropical maize) Annuals Advantages Fit into existing crop rotation Large production of biomass in one season Adds to species diversity C 3 and C 4 species Disadvantages Annual planting Grower expertise lacking Harvest technology Biomass storage Courtesy NRCS
Perennials Dedicated Energy Crops Perennials (switchgrass, alfalfa, Miscanthus) Advantages Long rotation (multi-years of production) Plant once, harvest for many years Suited to more fragile or marginal lands Fewer inputs (debatable) Knowledge based on inefficient harvest systems (grazing) Systems with low expected production (CRP) Disadvantages Grower expertise lacking Harvest technology Biomass storage May become a monoculture to meet biomass demand (billion tons)
Dedicated Energy Crops Where will they fit? A 50-million gallon Ethanol Plant Will Require: 125,000 acres of switchgrass assuming 5 tons/acre and 80 gallons of ethanol/ton of switchgrass. The Upper Big Blue NRD has 1.83 million acres, 1 million irrigated acres, and 4,600 center pivots. This NRD could grow 128,800 acres of switchgrass in pivot corners alone. Has 4 existing corn ethanol plants. 25-mile radius
Current switchgrass cultivars & agronomics equivalent to 1960 s corn system Switchgrass technology similar to1960 s corn and Volkswagen a basic, reliable system with improvement potential. Corn yield improvement 50% genetic-50% agronomics
Improving biomass yields hybrid cultivars Strain Kanlow & Summer F1 s Kanlow Summer Yield T/A (Mg/ha) 9.4 (21) 7.1 (16) 6.1 (14) Improved hybrid cultivars with modified cell walls could improve ethanol yields & reduce costs.
Over-arching Concerns Maximize capture and use of solar radiation and other inputs Create innovative cropping systems and technologies Continuously and adequately fund R&D to achieve bioenergy goals Coherent, coordinated energy policy Establish social environment of conservation
Multiple biomass feedstocks Many technologies Conservation Reduced expectations Asking, and answering, the right question