|
|||||||||||||
|
THE tiniest living organisms on Earth could become key to addressing some of the world’s biggest energy challenges. For decades, researchers have pursued energy generation by bacterial processes, most recently through the development and wider application of microbial fuel cells (MFCs), devices that convert biomass directly into electricity. These bioreactors are powered by select strains of bacteria capable of oxidizing organic matter and transferring electrons from their outer cell surface to an external electrode, thereby producing electrical current. But for all the ingenuity behind this technology, practical applications for MFCs have been limited because of the low efficiency of the bacterial energy conversion. Livermore scientists are currently seeking ways to maximize microbial-based energy generation and develop novel applications for MFC technologies and the special bacteria that power them. Fang Qian, a scientist in the Physical and Life Sciences Directorate, is leading a study to demonstrate enhanced MFC performance using the Shewanella oneidensis MR-1 bacteria and a unique bioreactor design that incorporates carbon cloth electrodes with micro-size chambers. In experiments, the device yielded a power output of 250 nanowatts (billionths of a watt)—an order of magnitude increase in performance compared to most previously reported MFCs of similar dimensions. Qian views this accomplishment as a first step toward developing new MFC technologies that integrate improved microbial metabolism with advances in materials science and fuel cells. Qian’s goal is to design and build novel bioelectrical systems that combine a variety of renewable energy sources, including solar power. Ultimately, she aims to couple MFCs and solar cells to produce hydrogen, creating a hybrid system that supports more efficient and environmentally friendly energy production. Electrogenic Bacteria Fuel Bioreactors This characteristic makes electrogenic bacteria excellent candidates for use in electricity-generating devices. MFCs use a pair of battery-like terminals (anode and cathode electrodes) connected to an external circuit and an electrolyte solution to conduct electricity. When bacteria physically attach to the anode, electrons generated in the interior of the cell are transferred to an external electrode, producing electrical current. “Because bacteria are some of the oldest living systems on the planet, they have invented ways to interact with the environment very efficiently,” explains microbiologist Michael Thelen, Qian’s mentor at the Laboratory. “As an example, they are able to gain energy from minerals. We can exploit this process by isolating the bacteria and then examining their genes and the encoded proteins that are actively involved in the electron transfer.” Most of Qian’s research into electron transfer pathways has focused on Shewanella, a dissimilatory metal-reducing bacteria considered a model microbe for fundamental research. The bacterium, which she used in the optimized micro-MFC study, is well understood and easy to identify, culture, and manipulate. But for all its great qualities, Shewanella is inefficient at generating power because it cannot completely oxidize organic compounds to maximize the energy extraction process. Moreover, a pure culture such as Shewanella always generates less power than do mixed cultures that contain a rich variety of microorganisms, including perhaps yet-unidentified electrogenic bacteria. Such microbial assemblies, or communities, can be found in natural environments or in municipal wastewater—a potential gold mine for bacterial prospectors like Qian and Thelen, who seek to improve MFCs. Turning Wastewater into Drinking Water The research, funded by the Laboratory Directed Research and Development Program, is a collaboration with the University of California at Santa Cruz and the Livermore Water Reclamation Plant. During the first year of the project, Qian and her colleagues have designed different devices that can generate electricity from wastewater. Once they achieve a self-sustaining, continuous-flow system in a laboratory setting, they plan to scale up the device to operate continuously in the water plant. By the end of this year, the team wants to produce hydrogen from wastewater as well, which would add value to the water reclamation process. More importantly, Qian’s research with bacterial communities could lead to the discovery of new, more efficient strains of electrogenic bacteria. Scientists are constantly searching for microbes with performance characteristics that will improve the bacterial-colonizing anode. As microbes are found, their genomes can be sequenced for optimizing future microbial technologies. “Our research could open up a whole new world for bioenergy applications,” says Thelen. Adding a Solar Device The hybrid system takes advantage of the best features of both technologies. Semiconductors transfer electrons at a much faster rate than microbial systems do, but most semiconductors need additional external electrical input to work as photoelectrodes. “Fang’s idea was to couple the two systems so that the bacteria will provide that extra energy,” says Thelen. For now, the solar-driven microbial reactor is not envisioned as a competitor to solar cells because microbial systems are intrinsically slower than semiconductors. Instead, the team would like to use this device to enhance the capabilities of water reclamation plants and to sow the seeds of future research. “Microbes are easy to work with and they reproduce,” says Thelen. “Just give them a little food, which we can get from sludge, and we have an infinite supply.” While applications for MFC technologies are still in their infancy, Qian’s creative uses of electrogenic bacteria for energy harvest and environmental applications are providing a glimpse into their future potential. One day, solar-driven devices that incorporate microbial photoelectrochemical cells may be useful on military bases or in other operations that necessitate the transport of water to remote facilities. Having the capability to treat and purify water locally in such environments could prove extremely valuable. In the meantime, the research conducted at Livermore is improving our fundamental understanding of key processes at the interface of biology, environmental science, nanotechnology, genetics, and other disciplines that will define science in this century. —Monica Friedlander Key Words: bioanode, electrogenic bacteria, microbial fuel cell (MFC), Shewanella oneidensis MR-1, solar-driven microbial photoelectrochemical cell, transmembrane protein. For further information contact Fang Qian (925) 424-5634 (qian3@llnl.gov).
|
||||||||||||
S&TR Home | LLNL
Home | LLNL Site Map | Top Lawrence Livermore National Laboratory Privacy & Legal Notice | UCRL-TR-52000-12-3 | March 9, 2012
|