Polymer Electrolyte Membrane Brings
Micro Fuel Cell Closer

Jun 10, 2004 4:29 PM
Edited by PETech Staff

A new type of polymer electrolyte membrane (PEM) is being developed by researchers at the Department of Energy’s Sandia National Laboratories to help bring the goal of a micro fuel cell closer to realization using diverse fuels such as glucose, methanol and hydrogen.

This Sandia Polymer Electrolyte Alternative (SPEA) could help fulfill the need for new, uninterrupted autonomous power sources for sensors, communications, microelectronics, healthcare applications and transportation.

The membrane research is one part of a three-year internally funded Bio-Micro Fuel Cell Grand Challenge led by Chris Apblett, Sandia principal investigator, and Kent Schubert, Sandia project manager.

Recently the membrane research team, headed by Sandia researcher Chris Cornelius, demonstrated that the new SPEA could operate as high as 140 °C and produce a peak power of 1.1 W/sq cm at 2 A/sq cm at 80 °C. Under identical operating conditions, the SPEA material can deliver higher power outputs with methanol and hydrogen than Nafion, which is recognized as the state-of-art PEM material for fuel cells.

Because the SPEA material can operate at elevated temperatures, it enables several key benefits that Nafion cannot provide. These advances include smaller fuel cell stacks because of better heat rejection, enhanced water management, and significant resistance to carbon monoxide poisoning. These performance properties suggest that the SPEA material may be a potential alternative to Nafion.

Cornelius notes that a higher temperature PEM material is one of the goals of the DOE’s Hydrogen Fuel Cells, and Infrastructure Technologies Program. One goal is to develop polymer electrolyte membranes for automotive applications that operate at 120 °C for 2000 hr with low membrane interfacial resistance by 2005.

Of the new SPEA material that Cornelius and Sandia researcher Cy Fujimoto developed, Cornelius says, “Validation of this material as a Nafion alternative would be a significant achievement, an accomplishment we strongly desire.” A polymer electrolyte membrane is a critical component of a working fuel cell. Its function is to conduct protons efficiently and possess low fuel crossover properties. It must also be robust enough to be assembled into a fuel cell stack and have long life.

In developing the SPEA material, the team looked at the success and limitations of other PEM alternatives in order to develop a set of characteristics for their model material. “At the beginning of this project we were considering several polymer families for a PEM alternative, including a family of polyphenylenes,” Cornelius says. “When the physical properties of one of the polyphenylenes being considered as a polymer electrolyte was improved and integrated into a working fuel cell, we happily discovered that it works extremely well compared to Nafion.”

Cornelius says that the SPEA material he and Fujimoto are developing “may be an enabling material that could have an impact on the fuel cell community and help Sandia become recognized as a fuel cell research organization.”

The next steps, Cornelius says, are to reduce the internal resistance in the fuel cell membrane electrode assembly, optimize catalyst and ionomer composition, improve the properties of the SPEA material, conduct life cycle testing in a fuel cell environment, and assess the potential value for large-scale commercialization of the polymer electrolyte. Understanding the material’s capabilities and limitations are necessary steps in order to potentially improve the physical properties of SPEA material.

“We see this SPEA material as having the potential of being integrated into fuel cells ranging from microwatts to kilowatts,” he says. “Such a broad power range means that this Sandia Polymer Electrolyte Alternative could be used in a fuel cell to power everything from sensors, cell phones, laptops, and automobiles.”

For more information, visit www.eere.energy.gov/hydrogenandfuelcells.

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