Home > Press > Carbon-coated iron catalyst structure could lead to more-active fuel cells
 |
| Illinois professor Andrew Gerwith and graduate student Jason Varnell developed a method to isolate active catalyst nanoparticles from a mixture of iron-containing compounds, a finding that could help researchers refine the catalyst to make fuel cells more active.
Photo by L. Brian Stauffer |
Abstract:
Fuel cells have long held promise as power sources, but low efficiency has created obstacles to realizing that promise. Researchers at the University of Illinois and collaborators have identified the active form of an iron-containing catalyst for the trickiest part of the process: reducing oxygen gas, which has two oxygen atoms, so that it can break apart and combine with ionized hydrogen to make water. The finding could help researchers refine better catalysts, making fuel cells a more energy- and cost-efficient option for powering vehicles and other applications.
Carbon-coated iron catalyst structure could lead to more-active fuel cells
Champaign, IL | Posted on September 15th, 2016Led by U. of I. chemistry professor Andrew Gewirth, the researchers published their work in the journal Nature Communications.
Iron-based catalysts for oxygen reduction are an abundant, inexpensive alternative to catalysts containing precious metals, which are expensive and can degrade. However, the process for making iron-containing catalysts yields a mixture of different compounds containing iron, nitrogen and carbon. Since the various compounds are difficult to separate, exactly which form or forms behave as the active catalyst has remained a mystery to researchers. This has made it difficult to refine or improve the catalyst.
“Previously, we didn’t know what these catalysts were made of because they had a lot of different things inside them,” Gewirth said. “Now we’ve narrowed it down to one component. Since we know what it looks like, we can change it and work to make it better.”
The researchers used a chlorine gas treatment to selectively remove from the mixture particles that were not active for oxygen reduction, refining the mixture until one type of particle remained: a carbon-encapsulated iron nanoparticle.
“We were left with only nanoparticles encapsulated within a carbon support, and that allows them to be more stable,” said Jason Varnell, a graduate student and the first author of the paper. “Iron oxidizes and corrodes on its own. You need to have the carbon around it in order to make it stable under fuel cell conditions.”
The researchers hope that narrowing down the active form of the catalyst can open new possibilities for making purer forms of the active catalyst, or for tweaking the composition to make it even more active.
“What’s the optimal size? What’s the optimal density? What’s the optimal coating material? These are questions we can now address,” Gewirth said. “We’re trying alternative methods for synthesizing the active catalyst and making multicomponent nanoparticles with certain amounts of different metals. Previously, people would add some metal salt into the tube furnace, like cooking – a little of this, a little of that. But now we know we also need to do things at different temperatures to put other metals in it. It gives us the ability to make it a more active catalyst.”
Ultimately, the researchers hope that improved catalyst function and manufacturability will lead to more-efficient fuel cells, which could make them useful for vehicles or other power-intensive applications.
“Now we understand the reactivity better,” Varnell said. “This could lead to the creation of more viable alternatives to precious metal catalysts.”
The National Science Foundation supported this work.
####
For more information, please click here
Contacts:
Liz Ahlberg Touchstone
217-244-1073
Andrew Gewirth
217-333-8329
Copyright © University of Illinois at Urbana-Champaign
If you have a comment, please Contact us.Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.
Bookmark:
| Related Links |
| Related News Press |
News and information
Sensors innovations for smart lithium-based batteries: advancements, opportunities, and potential challenges August 8th, 2025
Deciphering local microstrain-induced optimization of asymmetric Fe single atomic sites for efficient oxygen reduction August 8th, 2025
Lab to industry: InSe wafer-scale breakthrough for future electronics August 8th, 2025
Chemistry
Cambridge chemists discover simple way to build bigger molecules – one carbon at a time June 6th, 2025
Single-atom catalysts change spin state when boosted by a magnetic field June 4th, 2025
Quantum interference in molecule-surface collisions February 28th, 2025
Chainmail-like material could be the future of armor: First 2D mechanically interlocked polymer exhibits exceptional flexibility and strength January 17th, 2025
Govt.-Legislation/Regulation/Funding/Policy
New imaging approach transforms study of bacterial biofilms August 8th, 2025
Electrifying results shed light on graphene foam as a potential material for lab grown cartilage June 6th, 2025
Institute for Nanoscience hosts annual proposal planning meeting May 16th, 2025
Possible Futures
ICFO researchers overcome long-standing bottleneck in single photon detection with twisted 2D materials August 8th, 2025
New molecular technology targets tumors and simultaneously silences two ‘undruggable’ cancer genes August 8th, 2025
Simple algorithm paired with standard imaging tool could predict failure in lithium metal batteries August 8th, 2025
First real-time observation of two-dimensional melting process: Researchers at Mainz University unveil new insights into magnetic vortex structures August 8th, 2025
Discoveries
Deciphering local microstrain-induced optimization of asymmetric Fe single atomic sites for efficient oxygen reduction August 8th, 2025
ICFO researchers overcome long-standing bottleneck in single photon detection with twisted 2D materials August 8th, 2025
New molecular technology targets tumors and simultaneously silences two ‘undruggable’ cancer genes August 8th, 2025
Simple algorithm paired with standard imaging tool could predict failure in lithium metal batteries August 8th, 2025
Announcements
Sensors innovations for smart lithium-based batteries: advancements, opportunities, and potential challenges August 8th, 2025
Deciphering local microstrain-induced optimization of asymmetric Fe single atomic sites for efficient oxygen reduction August 8th, 2025
Japan launches fully domestically produced quantum computer: Expo visitors to experience quantum computing firsthand August 8th, 2025
ICFO researchers overcome long-standing bottleneck in single photon detection with twisted 2D materials August 8th, 2025
Automotive/Transportation
Sensors innovations for smart lithium-based batteries: advancements, opportunities, and potential challenges August 8th, 2025
Simple algorithm paired with standard imaging tool could predict failure in lithium metal batteries August 8th, 2025
Leading the charge to better batteries February 28th, 2025
Fuel Cells
Deciphering local microstrain-induced optimization of asymmetric Fe single atomic sites for efficient oxygen reduction August 8th, 2025
Current and Future Developments in Nanomaterials and Carbon Nanotubes: Applications of Nanomaterials in Energy Storage and Electronics October 28th, 2022
 |
||
 |
||
| The latest news from around the world, FREE | ||
 |
||
|
|
||
| Premium Products | ||
 |
||
|
Only the news you want to read!
Learn More |
||
 |
||
|
Full-service, expert consulting
Learn More |
||
|
|
||