Gu Lin-Fei, Chen Jun-Jia, Zhou Tao, Lu Xue-Feng, Li Gao-Ren
MOE Key Laboratory of Bioinorganic and Synthetic Chemistry, School of Chemistry, Sun Yat-Sen University, Guangzhou 510275, P.R. China.
Nanoscale. 2020 May 28;12(20):11201-11208. doi: 10.1039/d0nr02030c.
The development of efficient electrocatalysts for overall water splitting is important for future renewable energy systems. Herein, macroporous CoO covered by Co/N-doped graphitic carbon nanosheet arrays (mac-CoO@Co/NGC NSAs) were constructed by engineering a mesoporous CoO nanowire (mes-CoO NWAs) core with highly conductive Co nanoparticles coated by a N-doped graphitic carbon (Co/NGC) shell. The in situ derived Co/NGC shell not only introduces electrocatalytic active sites for the hydrogen evolution reaction (HER) but also promotes the oxygen evolution reaction (OER) through the strong interaction between the CoO core and the Co/NGC shell. Moreover, the highly conductive Co/NGC shell crosslinks the isolated mesoporous CoO nanowires into a nanosheet rich in macropores, ensuring effective electron and mass transfer. Furthermore, the chemically stable N-doped graphitic carbon layer and physically stable hierarchical nanosheet arrays ensure the stability of the catalyst. Owing to the desirable interfaces and pore architecture, the as-prepared mac-CoO@Co/NGC NSAs can serve as highly effective, binder-free electrocatalysts for overall water splitting with a stable cell voltage of 1.62 V at 10 mA cm-2 for 35 h.
开发用于全水分裂的高效电催化剂对未来的可再生能源系统至关重要。在此,通过设计具有由氮掺杂石墨碳(Co/NGC)壳包覆的高导电性钴纳米颗粒的介孔氧化钴纳米线(mes-CoO NWAs)核,构建了由Co/N掺杂石墨碳纳米片阵列覆盖的大孔氧化钴(mac-CoO@Co/NGC NSAs)。原位衍生的Co/NGC壳不仅引入了用于析氢反应(HER)的电催化活性位点,还通过CoO核与Co/NGC壳之间的强相互作用促进了析氧反应(OER)。此外,高导电性的Co/NGC壳将孤立的介孔氧化钴纳米线交联成富含大孔的纳米片,确保了有效的电子和质量传递。此外,化学稳定的氮掺杂石墨碳层和物理稳定的分级纳米片阵列确保了催化剂的稳定性。由于具有理想的界面和孔结构,所制备的mac-CoO@Co/NGC NSAs可以作为高效、无粘结剂的全水分裂电催化剂,在10 mA cm-2下具有1.62 V的稳定电池电压,持续35小时。
