Corn waste potentially more than ethanol
“People are looking at using cellulose to make ethanol,” says Dr. Bruce E. Logan, the Kappe Professor of Environmental Engineering. “You can make ethanol from exploded corn stover, but once you have the sugars, you can make electricity directly.”
Logan's process uses a microbial fuel cell to convert organic material into electricity. Previous work has shown that these fuel cells can generate electricity from glucose and from municipal wastewater and that these cells can also directly generate hydrogen gas.
Corn stalks and leaves, amassing 250 million tons a year, make up a third of the total solid waste produced in the United States. Currently, 90 percent of corn stover is left unused in the field. Corn stover is about 70 percent cellulose or hemicellulose, complex carbohydrates that are locked in chains. A steam explosion process releases the organic sugars and other compounds in the corn waste and these compounds can be fed to microbial fuel cells.
The microbial fuel cells contain two electrodes and anaerobic bacteria – bacteria that do not need oxygen – that consume the sugars and other organic material and release electrons. These electrons travel to the anode and flow in a wire to the cathode, producing electrical current. The water in the fuel cell donates positive hydrogen atoms that combine with the electrons and oxygen to form water.
The microbial fuel cells were inoculated with domestic wastewater and a nutrient medium containing glucose, the researchers report in the journal Energy and Fuels. Once established, the bacteria colonies were fed the sugary organic liquid obtained from steam exploding of corn stover.
The researchers, who include Logan, Yi Zuo, Penn State graduate student in environmental engineering, and Pin-Ching Maness, senior scientist, National Renewable Energy Laboratory, report that “the conversion of organic matter to electricity, on the basis of biological oxygen demand removal, was relatively high with greater than 93 percent of the biological oxygen demand removed.”
In essence, there is no organic matter left to cause problems when disposing of the remaining liquid because there is nothing left to oxidize. The process converts all the available energy to electricity. The electrical production is about one watt for every square meter of surface area at about 0.5 volts. A typical light bulb uses 60 watts. To increase wattage, the surface area needs to increase. To increase voltage, fuel cells can be linked in series.
“Producing electricity from steam exploded corn stover adds to the energy diversity of our portfolio,” says Logan. “Electricity can be used to pump water uphill for later use, directly run light, heat and equipment or electrolyze water to create hydrogen.”
The Penn State researcher and colleagues have also used microbial fuel cells and wastewater to produce hydrogen gas directly.
Media Contact
More Information:
http://www.psu.eduAll latest news from the category: Power and Electrical Engineering
This topic covers issues related to energy generation, conversion, transportation and consumption and how the industry is addressing the challenge of energy efficiency in general.
innovations-report provides in-depth and informative reports and articles on subjects ranging from wind energy, fuel cell technology, solar energy, geothermal energy, petroleum, gas, nuclear engineering, alternative energy and energy efficiency to fusion, hydrogen and superconductor technologies.
Newest articles
Compact LCOS Microdisplay with Fast CMOS Backplane
…for High-Speed Light Modulation. Researchers from the Fraunhofer Institute for Photonic Microsystems IPMS, in collaboration with HOLOEYE Photonics AG, have developed a compact LCOS microdisplay with high refresh rates that…
New perspectives for material detection
CRC MARIE enters third funding period: A major success for terahertz research: Scientists at the University of Duisburg-Essen and the Ruhr University Bochum have been researching mobile material detection since…
CD Laboratory at TU Graz Researches New Semiconductor Materials
Using energy- and resource-saving methods, a research team at the Institute of Inorganic Chemistry at TU Graz aims to produce high-quality doped silicon layers for the electronics and solar industries….