Soybeans for Biodiesel Production

Farm Energy January 31, 2014|Print

The many benefits to using soybean oil in the production of biodiesel include, soybeans are widely grown, the infrastructure and equipment to grow, transport and process them already exists, and the left over soybean meal is important for animal feed. Read more about the advantages and drawbacks of soybeans as a biofuel energy crop.

One ton tote of soybeans
Soybeans.

Contents

Introduction

Soybean acreage is much greater than other oilseed crops, leading to substantial soybean oil production and its availability as a biofuel feedstock.

Soybean (Glycine max) is a major crop throughout much of North America, South America, and Asia. The United States is the world’s greatest producer, producing approximately 32% of the world's soybeans, followed by Brazil with 28%.

Soybean trials. Photo: Dennis Pennington, Bioenergy Educator, Michigan State University.

Soybeans originated in Southeast Asia, with first domestication reported in the 11th century BC in China. First planted in the United States in 1765, soybeans spread to the Corn Belt by the mid-1800s with major acreage not seen until the 1920s, when it was used mainly as a forage crop. Major U.S. expansion as an oilseed crop began in the 1940s (Gibson and Benson, 2005).

Soybeans contain approximately 18% to 20% oil compared to other oilseed crops such as canola (40%) and sunflower (43%) (Berglund et al., 2007; National Sunflower Association 2009). At 48 pounds per bushel, soybean meal remains a major product from soybeans and is used for animal feed and human food.

Current Potential for Use as a Biofuel

Soybean oil is currently a major feedstock for production of biodiesel (NBB). The most common method of biodiesel production is a reaction of vegetable oils or animal fats with methanol or ethanol in the presence of sodium hydroxide (which acts as a catalyst). The transesterification reaction yields methyl or ethyl esters (biodiesel) and a byproduct of glycerin.

Note that biodiesel is not straight vegetable oil burned in a diesel engine. Numerous studies between 1980 and 2000 have shown the use of straight vegetable oil, including soybean oil, causes carbon deposits and shortens engine life (Jones and Peterson 2002).

Biodiesel use in diesel engines does not have similar negative effects. Use of soybean oil for biodiesel was greatly influenced by promotion from U.S. soybean farmers through the United Soybean Board (USB) and subsequent creation of the National Biodiesel Board (NBB).

Biology and Adaptation

Soybean is a cool-season legume which can be grown from south to north throughout much of the eastern half of the United States. Soybeans and other legumes have a unique relationship with a bacteria bradyrhizobium species, which will colonize on soybean roots, forming a nodule. The two species form a symbiotic relationship in which the soybean plant provides nutrition and the bacteria fixes nitrogen from the air. This relationship reduces the need for supplemental nitrogen fertilizer in soybean production.

Soybeans flower in response to day length and temperature. Varieties grown in the United States are divided into 13 maturity groups, from maturity group 000, which is the earliest and adapted to northern regions of Minnesota and southern Canada, to maturity group X, adapted to southern regions such as south Texas. The earlier varieties bloom when days are long and nights are short, while the later-maturing varieties bloom under relatively shorter days and longer nights. Summer days are longer at northern latitudes, where early-maturing varieties will initiate flowering when days are longer. Maturity groups develop differently, and knowing the growth habit of different maturity groups can help with the crop management (Waitrak et al., 2010).

Soybean Maturity Zones Map: https://netfiles.uiuc.edu/tjw/www/scn_map.htm

Production and Agronomic Information

Through much of the upper Midwest, soybeans are planted in April to June and harvested in September to November. Soybeans are well adapted to grow in soils similar to corn production. In many cases, soybeans are grown in rotation with corn or wheat to break insect, weed, and disease cycles.

Nutrient requirements are generally less for soybeans than other crops. Major nutrient requirements include nitrogen, phosphorous, and potassium. Much of the nitrogen is gained through a relationship with bacteria. A soil pH in the range of 5.5 to 7.0 will enhance nutrient availability and soybean growth (Ferguson et al., 2006).

Weed control is necessary to achieve optimal yields, and use of biotech seeds has eased the ability to control weeds during the growing season. Currently in the United States, over 90% of soybeans planted are herbicide resistant (USDA ERS, 2009).

Many insects and diseases are common in soybeans grown in the upper Midwest. The most damaging pest to soybeans is soybean cyst nematode, a soil-borne parasitic roundworm that feeds on soybean roots (Chen et al., 2001). Insect pests include bean leaf beetle, soybean aphid, green clover worm, and spider mites. Soybean harvest begins after 95% leaf senescence when beans are at 12% to 18% moisture.

Potential Biofuel Yields

Harvesting soybeans in Nebraska.  Photo: F. John Hay, Extension Educator, University of Nebraska-Lincoln Extension.

Current U.S. production of soybeans in 2009 was 3.4 billion bushels from 77.4 million acres. Average yield per acre for the United States was 44 bushels per acre (National Agricultural Statistics Service). One bushel of soybeans can yield 1.5 gallons of biodiesel (NBB). Using all U.S. soybeans for biodiesel could produce 5.1 billion gallons of biodiesel. However, using all soybean production for biodiesel has not been proposed and is not realistic.

In 2009, biodiesel production was 700 million gallons with a production capacity of 1.83 billion gallons (Biodiesel Magazine, 2008). Based on a yield of 44 bushels per acre, an acre of soybeans could yield 66 gallons of biodiesel, compared to 69 gallons for a 1,300-lb per acre canola yield, 84 gallons for sunflower and over 600 gallons for palm oil (Hill et al., 2006 and SDSU, 2008).

Production Challenges

Soybean production generally complements corn production in the upper Midwest. Both corn and soybeans enjoy a long history of production on millions of acres in the upper Midwest. This history has led to a large infrastructure of equipment, storage, rail, barge, and truck transportation.

Soybeans, like many crops, face insect and disease pests along with weather-related challenges. An emerging disease has gained much attention in recent years. Soybean rust, a fungal disease native to Asia, has spread to the soybean fields of South America and finally to U.S. soybeans. Rust control is expensive, requiring fungicide applications, and yield damage can be extreme.

Estimated Production Costs

Production costs will vary depending on location, cropping systems, and fluctuation in price of energy. Major expenditures in soybean production include planting, harvesting, seed, and pesticides. An example of a Nebraska rain-fed budget for no-till soybeans for 2010 lists $115 per acre for field operations, materials, and services. When including overhead costs for land, insurance, etc., the total is approximately $200 per acre. Total costs for irrigated soybeans are around $400 per acre (Klein and Wilson, 2010).

Biodiesel profitability is extremely variable and based on the continuously changing prices of biodiesel, soybean oil, co-product glycerin, methanol, and natural gas. Price of soybean oil feedstock is one of the driving factors in profitability (Hofstrand and Johanns, 2010).

Environmental and Sustainability Issues

The capacity of soybeans used for biodiesel production grew from zero to over a billion gallons per year in the past two decades (1990s and 2000s). During that time, biodiesel production rose and fell depending on the price of feedstock, price of petroleum oil, and federal and state subsidies provided to the industry.

One major challenge for soybeans is the competing uses for soybean oil. Soybean oil is used in human food products, as cooking oil, and for numerous industrial applications. Soybeans account for 80% or more of the edible fats and oils consumed in the United States (Gibson and Benson, 2005). Competition with other uses has caused price spikes in the soybean oil market, challenging the profitability of soybean biodiesel (Wisner, 2009).

A 2009 life cycle analysis of biodiesel done by the USDA found that soy biodiesel yields 4.56 times the fossil energy needed to produce it. In comparison, petroleum diesel has a fossil energy ration of 0.84 (Pradhan et al., 2009, pp. iii-iv).

For Additional Information

Related Topics

Soybean Production and Management

Bibliography

Biodiesel Magazine, (2008), 2009 Biodiesel Industry Directory, Fifth Edition December 2008, BBI International, Grand Forks, ND.

Berglund D.R., McKay K., Knodel J., (2007), Canola Production, North Dakota State University, A-686 revised August 2007.

Chen S., MacDonald D.H., Kurle J.E. Reynolds D.A., 2001, The Soybean Cyst Nematode, University of Minnesota Extension, FO-03935, http://www.soybeans.umn.edu.

Energy Information Administration, http://www.eia.gov/.

Environmental Protection Agency, http://www.EPA.gov,

Ferguson R.B., Shapiro C.A., Dobermann A.R., Wortmann C.S., (2006), Fertilizer Recommendations for Soybeans, University of Nebraska-Lincoln Extension, G859.

Gibson L. and Benson G., (2005), Origin, History, and Uses of Soybeans (Glycine max), Iowa State University, Department of Agronomy, http://www.agron.iastate.edu.

Hill A., Kurki A., Morris M., (2006), Biodiesel: The Sustainability Dimensions, ATTRA Publication. Butte, MT: National Center for Appropriate Technology. Pages 4-5.

Hoeft R.G., Nafziger E.D., Johnson R.R., (2000), Aldrich S.R. Modern Corn and Soybean Production, MCSP Publications, Champaign, IL.

Hofstrand D., Johanns A., (2010) Ag Marketing Resource Center, Biodiesel Profitability, Iowa State University Extension.

Jones S., Peterson C.L., (2002) Using Unmodified Vegetable Oils as a Diesel Fuel Extender - A Literature Review. Department of Biological and Agricultural Engineering, University of Idaho, Moscow.

Klein R.N., and Wilson R.K., (2010), Crop Budgets Nebraska 2010, University of Nebraska-Lincoln Extension, EC 872, http://www.ianrpubs.unl.edu/epublic/live/ec872/build/ec872.pdf.

National Biodiesel Board (NBB), http://biodiesel.org.

National Agriculture Statistics Service (NASS), http://www.nass.usda.gov.

National Sunflower Association, (2009), 2009 U.S. Sunflower Crop Quality Report, Mandan, ND, http://www.sunflowernsa.com.

Pradhan, A., Shrestha, D. S., McAloon, A., Yee, W., Haas, M., Duffield, J.A., and Shapouri, H. (2009) Energy Life-Cycle Assessment of Soybean Biodiesel. United States Department of Agriculture, Agricultural Economic Report Number 845.

Renewable Fuel Association, http://www.ethanolrfa.org.

South Dakota State University Extension, (2008), Sunflower 2008 South Dakota Hybrid Performance Trials, SDSU Extension, EC 909 revised annually.

United State Department of Agriculture Economic Research Service, (2009), Adoption of Genetically Engineered Crops in the U.S.: Soybean Varieties, http://www.ers.usda.gov.

Wiatrak P., Shipe E., Norsworthy J., (2010) Soybean Maturity Groups and Growth Habit, Clemson University Soybean Production Website, http://www.clemson.edu.

Wisner R., (2009), Biodiesel economics – costs, tax credits and coproduct, Agricultural marketing resource center (AgMRC). AgMRC Renewable Energy Newsletter, June 2009 http://www.agmrc.org.

Contributors to This Article

Author

Peer Reviewers


Connect with us

  • Twitter
  • Facebook
  • Google+

Welcome

eXtension is an interactive learning environment delivering research-based information emerging from America's land-grant university system.

LOCATE

Donate to Sustainable Ag Energy

Your donation keeps eXtension growing.

Give Now