副教授
硕士生导师
教师拼音名称:yujianhua
学历:博士研究生
学位:工学博士
职称:副教授
毕业院校:中科院上海硅酸盐研究所
邮箱:
2020-06-08 青岛科技大学毕业生最喜爱的老师
2019-12-31 青岛科技大学先进工作者
2016-12-31 青岛科技大学先进工作者
最后更新时间:..
关键字:METAL-ORGANIC FRAMEWORK; POROUS CARBON; EVOLUTION; REDUCTION; CATALYSTS; GRAPHENE; NANOSHEETS; NETWORKS; FILM; CO
摘要:The rational design and synthesis of efficient and durable bifunctional electrocatalysts for oxygen reduction reactions (ORRs) and oxygen evolution reactions (OERs) is significant yet challenging for rechargeable Zn-air batteries. Up to now, most attention has been focused on the ORR performance, but the disproportion of OER proficiencies results in poor cycling capabilities and energy waste during charging process. Herein, a dual-active site hierarchical composite (Co-NC@LDH) is constructed by anchoring high OER-active NiFe layered double hydroxide (NiFe-LDH) nanosheets on the surface of ORR-active ZIF-derived carbon-based framework. This design fully utilizes their advantages and synergistic effects, such as good conductivity, hierarchical structure, ORR-active sites of Co, N-codoped carbon (Co-NC) substrate and OER-active sites of NiFe-LDH, to optimize bifunctional catalytic performance and durability in Zn-air batteries. The Co-NC@LDH demonstrates a lower overpotential of 819 mV than single component Co-NC (893 mV), NiFe-LDH (1178 mV) and noble-metal catalysts (957 mV for Pt/C and 1118 mV for RuO2) in alkaline media. Impressively, a high peak power density (107.8 mW cm-2) and excellent durability (over 300 h) are exhibited by Zn-air batteries based on Co-NC@LDH as electrocatalyst. This work provides a facile, low-cost and environmental-friendly strategy to synthesize bifunctional catalysts for efficient and durable zinc-air batteries.
卷号:399
是否译文:否