AI Article Synopsis
- This study focuses on nitrogen-doped carbon materials with hollow spherical structures as catalysts for the oxygen reduction reaction (ORR), showcasing their effectiveness in alkaline media.
- The nitrogen-doped hollow carbon spheres (N-CHS) have unique features like a thin shell, large surface area, and porous structure, enhancing reaction efficiency and active site exposure.
- Using heme chloride for Fe doping during carbonization, the modified catalyst achieves a notable half-wave potential and performs well in zinc-air batteries, demonstrating a power density of 162.6 mW cm.
Article Abstract
Extensive investigations have been devoted to nitrogen-doped carbon materials as catalysts for the oxygen reduction reaction (ORR) in various conversion technologies. In this study, we introduce nitrogen-doped carbon materials with hollow spherical structures. These materials demonstrate significant potential in ORR activity within alkaline media, showing a half-wave potential of 0.87 V versus the reversible hydrogen electrode (RHE). Nitrogen-doped hollow carbon spheres (N-CHS) exhibit unique characteristics such as a thin carbon shell layer, hollow structure, large surface area, and distinct pore features. These features collectively create an optimal environment for facilitating the diffusion of reactants, thereby enhancing the exposure of active sites and improving catalytic performance. Building upon the promising qualities of N-CHS as a catalyst support, we employ heme chloride (1 wt%) as the source of iron for Fe doping. Through the carbonization process, Fe-N active sites are effectively formed, displaying a half-wave potential of 0.9 V versus RHE. Notably, when implemented as a cathode catalyst in zinc-air batteries, this catalyst exhibits an impressive power density of 162.6 mW cm.
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