A pH-dependent microkinetic modeling guided synthesis of porous dual-atom catalysts for efficient oxygen reduction in Zn–air batteries
Energy Environ. Sci., 2025, 18,4949-4961DOI: 10.1039/D5EE00215J, Paper Open Access   This article is licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported Licence.Tingting Li, Di Zhang, Yun Zhang, Danli Yang, Runxin Li, Fuyun Yu, Kengqiang Zhong, Xiaozhi Su, Tianwei Song, Long Jiao, Hai-Long Jiang, Guo-Ping Sheng, Jie Xu, Hao Li, Zhen-Yu WuGuided by the pH-field microkinetic model, we developed an porous Fe1Co1–N–C ORR catalyst, which exhibited excellent performance in zinc–air batteries and provided insights for advanced catalysts.The content of this RSS Feed (c) The Royal Society of Chemistry
Energy Environ. Sci., 2025, 18,4949-4961
DOI: 10.1039/D5EE00215J, Paper
DOI: 10.1039/D5EE00215J, Paper
Open Access
This article is licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported Licence.Tingting Li, Di Zhang, Yun Zhang, Danli Yang, Runxin Li, Fuyun Yu, Kengqiang Zhong, Xiaozhi Su, Tianwei Song, Long Jiao, Hai-Long Jiang, Guo-Ping Sheng, Jie Xu, Hao Li, Zhen-Yu Wu
Guided by the pH-field microkinetic model, we developed an porous Fe1Co1–N–C ORR catalyst, which exhibited excellent performance in zinc–air batteries and provided insights for advanced catalysts.
The content of this RSS Feed (c) The Royal Society of Chemistry
Guided by the pH-field microkinetic model, we developed an porous Fe1Co1–N–C ORR catalyst, which exhibited excellent performance in zinc–air batteries and provided insights for advanced catalysts.
The content of this RSS Feed (c) The Royal Society of Chemistry
