College of Transportation Engineering, Dalian Maritime University, Dalian 116026, China.
Dalton Trans. 2023 Feb 21;52(8):2373-2383. doi: 10.1039/d2dt03522g.
High activity bifunctional oxygen electrocatalysts are crucial for the development of high performing Zn-air batteries. Fe-N-C systems decorated with Fe/FeC nanoparticles have been identified as prospective candidates in which almost all the active sites need the presence of N. To anchor more N, an FeO microsphere template was covered by a thin layer of polymerized dopamine (PDA) before it was mixed with a high N-content source of g-CN. The PDA interlayer not only provides a part of C and N but also serves as a buffer agent to hinder fast reactions between FeO and g-CN during pyrolysis to avoid the destruction of the microsphere template. The prepared Fe/FeC@FeNC catalyst showed superior electrochemical performance, achieving a high half-wave potential of 0.825 V for ORR and a low overpotential of 1.450 V at 10 mA cm for OER. The rechargeable Zn-air battery assembled with the as-obtained Fe/FeC@FeNC catalyst as a cathode offered a high peak energy density of 134.6 mW cm, high specific capacity of 856.2 mA h g and excellent stability over 180 h at 5 mA cm (10 min per cycle) with a small charge/discharge voltage gap of ∼0.851 V. This work presents a practical strategy for constructing nitrogen-rich catalysts with stable 3D structures.
高活性双功能氧电催化剂对于高性能锌空气电池的发展至关重要。在 Fe-N-C 体系中,负载 Fe/FeC 纳米颗粒的体系被认为是很有前途的候选材料,因为其中几乎所有的活性位点都需要 N 的存在。为了锚定更多的 N,FeO 微球模板先用聚合多巴胺 (PDA) 覆盖一层薄薄的膜,然后再与高 N 含量的 g-CN 源混合。PDA 夹层不仅提供了一部分 C 和 N,而且还作为缓冲剂,在热解过程中阻碍 FeO 和 g-CN 之间的快速反应,以避免微球模板的破坏。所制备的 Fe/FeC@FeNC 催化剂表现出优异的电化学性能,对 ORR 的半波电位达到 0.825 V,对 OER 的过电位仅为 1.450 V(10 mA cm 时)。以所获得的 Fe/FeC@FeNC 催化剂作为阴极组装的可充电锌空气电池提供了高的峰值能量密度 134.6 mW cm、高的比容量 856.2 mA h g 和在 5 mA cm 下超过 180 h 的优异稳定性(每循环 10 min),具有小的充放电电压差 ∼0.851 V。这项工作提出了一种构建具有稳定 3D 结构的富氮催化剂的实用策略。
