The following news release is being distributed by the Georgia Institute of Technology about a new fuel cell anode catalyst that could lead to cleaner, cost-effective fuel cells powered by coal. Scientists from the U.S. Department of Energy’s Brookhaven National Laboratory used an advanced computing facility at the laboratory’s Center for Functional Nanomaterials to determine how the catalyst works. The authors of the paper also used Brookhaven’s National Synchrotron Light Source to characterize the catalytic reaction. For more information about Brookhaven’s role, contact Kendra Snyder at 631-344-8191, firstname.lastname@example.org or Peter Genzer at 631-344-3174, email@example.com.
June 22, 2011
Regents professor Meilin Liu holds a button fuel cell used to evaluate a new self-cleaning anode material based on barium oxide. The self-cleaning technique could allow fuel cells to be powered by coal gas. (Credit: Gary Meek).
Using barium oxide nanoparticles, researchers have developed a self-cleaning technique that could allow solid oxide fuel cells to be powered directly by coal gas at operating temperatures as low as 750 degrees Celsius. The technique could provide a cleaner and more efficient alternative to conventional power plants for generating electricity from the nation’s vast coal reserves.
Solid oxide fuel cells can operate on a wide variety of fuels, and use hydrocarbons gases directly — without a separate reformer. The fuel cells rely on anodes made from nickel and a ceramic material known as yttria-stabilized zirconia. Until now, however, carbon-containing fuels such as coal gas or propane could quickly deactivate these Ni-YSZ anodes, clogging them with carbon deposits in a process known as “coking” — especially at lower operating temperatures.
To counter this problem, researchers have developed a technique for growing barium oxide nanostructures on the anodes. The structures adsorb moisture to initiate a water-based chemical reaction that oxidizes the carbon as it forms, keeping the nickel electrode surfaces clean even when carbon-containing fuels are used at low temperatures.
“This could ultimately be the cleanest, most efficient and cost-effective way of converting coal into electricity,” said Meilin Liu, a Regents professor in the School of Materials Science and Engineering at the Georgia Institute of Technology. “And by providing an exhaust stream of pure carbon dioxide, this technique could also facilitate carbon sequestration without the separation and purification steps now required for conventional coal-burning power plants.”
The water-mediated carbon removal technique was reported June 21 in the journal Nature Communications. The research was supported by the U.S. Department of Energy’s Office of Basic Energy Sciences, through the HeteroFoaM Center, an Energy Frontier Research Center. The work also involved researchers from Brookhaven National Laboratory, the New Jersey Institute of Technology and Oak Ridge National Laboratory.
Conventional coal-fired electric generating facilities capture just a third of the energy available in the fuel they burn. Fuel cells can convert significantly more of the energy, approximately 50 percent. If gas turbines and fuel cells could be combined into hybrid systems, researchers believe they could capture as much as 80 percent of the energy, reducing the amount of coal needed to produce a given amount of energy, potentially cutting carbon emissions.
But that would only be possible if the fuel cells could run for long periods of time on coal gas, which now deactivates the anodes after as little as 30 minutes of operation.
The carbon removal system developed by the Georgia Tech-led team uses a vapor deposition process to apply barium oxide nanoparticles to the nickel-YSZ electrode. The particles, which range in size from 10 to 100 nanometers, form “islands” on the nickel that do not block the flow of electrons across the electrode surface.
When water vapor introduced into the coal gas stream contacts the barium oxide, it is adsorbed and dissociates into protons and hydroxide (OH) ions. The hydroxide ions move to the nickel surface, where they combine with the carbon atoms being deposited there, forming the intermediate COH. The COH then dissociates into carbon monoxide and hydrogen, which are oxidized to power the fuel cell, ultimately producing carbon dioxide and water. About half of the carbon dioxide is then recirculated back to gasify the coal to coal gas to continue the process.
“We can continuously operate the fuel cell without the problem of carbon deposition,” said Liu, who is also co-director of Georgia Tech’s Center for Innovative Fuel Cell and Battery Technologies.
The researchers also evaluated the use of propane to power solid oxide fuel cells using the new anode system. Because oxidation of the hydrogen in the propane produces water, no additional water vapor had to be added, and the system operated successfully for a period of time similar to the coal gas system.
Solid oxide fuel cells operate most efficiently at temperatures above 850 degrees Celsius, and much less carbon is deposited at higher temperatures. However, those operating temperatures require fabrication from special materials that are expensive — and prevent solid oxide fuel cells from being cost-effective for many applications.
Reducing the operating temperatures is a research goal, because dropping temperatures to 700 or 750 degrees Celsius would allow the use of much less expensive components for interconnects and other important components. However, until development of the self-cleaning process, reducing the operating temperature meant worsening the coking problem.
“Reducing the operating temperature significantly by eliminating the problem of carbon deposition could make these solid oxide fuel cells economically competitive,” Liu said.
Fuel cells powered by coal gas still produce carbon dioxide, but in a much purer form than the stack gases leaving traditional coal-fired power plants. That would make capturing the carbon dioxide for sequestration less expensive by eliminating large-scale separation and purification steps, Liu noted.
The researchers have so far tested their process for a hundred hours, and saw no evidence of carbon build-up. A major challenge ahead is to test the long-term durability of the system for fuel cells that are designed to operate for as long as five years. Researchers must also study the potential impact of possible fuel contaminants on the new electrode.
Forming the barium oxide structures can be done as part of conventional anode fabrication processes, and would not require additional steps. The anodes produced in the technique are compatible with standard solid oxide fuel cell systems that are already being developed for commercial electricity generation, home power generation and automotive applications.
“We have started with state-of-the-art technology, and simply modified the surface of the electrode,” said Mingfei Liu, a postdoctoral researcher in the Center. “Because our electrode would be built on existing technology, there is a lower barrier for implementing it in conventional fuel cell systems.”
In addition to those already mentioned, the research team included Lei Yang, Wentao Qin and Kevin Blinn from Georgia Tech; YongMan Choi and Ping Liu from Brookhaven National Laboratory; Haiyan Chen and Trevor Tyson from the New Jersey Institute of Technology, and Jianming Bai from Oak Ridge National Laboratory.
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