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Ag byproducts may soon become a fuel
MISSISSIPPI STATE -- Researchers at Mississippi State University are converting grasses and agricultural waste into energy, hoping to lower ethanol's cost enough to compete with gasoline as a fuel.
Researchers at MSU and Oklahoma State University are pursuing the conversion of biomass from switchgrass or agricultural byproducts into energy. This energy is in the form of either biofuels, such as ethanol, or electricity.
Mississippi has an estimated 4.75 million acres in crop and hay production. Jerry Gilbert, head of MSU's Agricultural and Biological Engineering Department, said the state has the potential to produce almost 13 million tons of biomass. This would come from dedicated acreage and salvaged agricultural residues, cotton gin and forest byproducts, and chicken litter.
"If the infrastructure were in place, Mississippi theoretically could convert its future waste and cultured biomass into 948 million gallons of biofuel or 7.58 billion kilowatt hours of electricity. That's enough to power 702,000 average homes for a year," Gilbert said.
MSU and OSU are looking at the gases produced in a gasifier by different plant-based materials and how efficiently these gases can be converted into energy. Gilbert said any cellulose-based material can be put into a gasifier and used to produce a synthesis gas, or syngas.
"Syngas is produced by burning plant material at a very high temperature to produce a mixture of gases such as carbon monoxide, carbon dioxide, hydrogen and methane," Gilbert said.
These gases can be directed into a generator to produce electricity or sent into a bioreactor to produce ethanol or some other desirable biofuel. A bioreactor is a vessel in which bacteria are grown in solution. Syngas is bubbled through the bioreactor where bacteria convert the gas through fermentation into compounds that are useful to industrial processes.
MSU has ordered a downdraft gasifier from a manufacturer in Littleton, Colo., and should have it in place by Aug. 15. Gilbert said this small unit will be ideal for research purposes, but staff first had to find a way to get the fuel into the gasifier.
"The gasifier has been designed for wood chips, and requires materials to be uniformly dense. Since several different substances are going to be tested in the gasifier, a way had to be developed to use different materials in it," Gilbert said.
Researcher Eugene Columbus found a used John Deere cuber that will form cut grasses into 1 1/4-inch cubes that can be fed directly into the gasifier.
"This will reduce transportation costs and possibly storage costs by doing the processing in the field," Gilbert said.
OSU designed their own gasifier, which uses a fluidized sand bed to incinerate biomass materials placed inside. With both land-grant universities working on this project, researchers will be able to test both different and similar biomass materials and the results of two different gasifiers.
Gilbert said producing ethanol from plant material using a gasifier and bioreactor is currently not as economical as producing it the traditional way through corn fermentation, which produces a known amount of ethanol. Ethanol has a higher production cost than do petroleum-based fuels. However, the research has the potential to dramatically reduce the cost.
"There's always a desire to find a better organism to produce ethanol," Gilbert said. "The goal of finding microorganisms for bioreactors is to identify and isolate these organisms that are better suited to ethanol production. Increased ethanol production by newly identified organisms will mean lower production costs for ethanol."
While researchers are trying to find microorganisms that produce greater amounts of ethanol, they are also looking at using different biomass materials to produce syngases of varying compositions. Microorganisms will respond differently to different syngas, and researchers want to learn what results will occur.
At MSU, the Mississippi Agricultural and Forestry Experiment Station is coordinating this research along with the Swalm School of Chemical Engineering, but the effort also involves MSU's Extension Service, College of Arts and Sciences, Forest Products Laboratory and the Diagnostic Instrumentation and Analysis Laboratory.
Contact: Dr. Jerry Gilbert, (662) 325-3282