Ta–TiOx nanoparticles as radical scavengers to improve the durability of Fe–N–C oxygen reduction catalysts
Hua Xie,
Xiaohong Xie,
Guoxiang Hu (),
Venkateshkumar Prabhakaran,
Sulay Saha,
Lorelis Gonzalez-Lopez,
Abhijit H. Phakatkar,
Min Hong,
Meiling Wu,
Reza Shahbazian-Yassar (),
Vijay Ramani,
Mohamad I. Al-Sheikhly,
Jiang De-en,
Yuyan Shao () and
Liangbing Hu ()
Additional contact information
Hua Xie: University of Maryland
Xiaohong Xie: Pacific Northwest National Laboratory
Guoxiang Hu: Queens College of the City University of New York
Venkateshkumar Prabhakaran: Pacific Northwest National Laboratory
Sulay Saha: Washington University in St. Louis
Lorelis Gonzalez-Lopez: University of Maryland
Abhijit H. Phakatkar: University of Illinois at Chicago
Min Hong: University of Maryland
Meiling Wu: University of Maryland
Reza Shahbazian-Yassar: University of Illinois at Chicago
Vijay Ramani: Washington University in St. Louis
Mohamad I. Al-Sheikhly: University of Maryland
Jiang De-en: University of California
Yuyan Shao: Pacific Northwest National Laboratory
Liangbing Hu: University of Maryland
Nature Energy, 2022, vol. 7, issue 3, 281-289
Abstract:
Abstract Highly active and durable platinum group metal-free catalysts for the oxygen reduction reaction, such as Fe–N–C materials, are needed to lower the cost of proton-exchange membrane fuel cells. However, their durability is impaired by the attack of oxidizing radicals such as ·OH and HO2· that form from incomplete reduction of O2 via H2O2. Here we demonstrate that Ta–TiOx nanoparticle additives protect Fe–N–C catalysts from such degradation via radical scavenging. The 5 nm Ta–TiOx nanoparticles were uniformly synthesized on a Ketjenblack substrate using a high-temperature pulse technique, forming the rutile TaO2 phase. We found that Ta–TiOx nanoparticles suppressed the H2O2 yield by 51% at 0.7 V in an aqueous rotating ring disk electrode test. After an accelerated durability test, a fuel cell prepared with the scavengers showed a current density decay of 3% at 0.9 ViR-free (internal resistance-compensated voltage); a fuel cell without scavengers showed 33% decay. Thus, addition of Ta–TiOx provides an active defence strategy to improve the durability of oxygen reduction reaction catalysts.
Date: 2022
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DOI: 10.1038/s41560-022-00988-w
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