Niu Yongjian, Zhang Chunhua, Wang Yuanyuan, Fang Dong, Zhang Linlin, Wang Cheng
Institute for New Energy Materials and Low-Carbon Technologies, School of Material Science and Engineering, Tianjin University of Technology, Tianjin, 300384, P. R. China.
Unilever Co., Ltd., 88# Jinxiu Avenue, Economy & Technology Dev. Zone, Hefei, 230000, P. R. China.
ChemSusChem. 2021 Feb 18;14(4):1140-1154. doi: 10.1002/cssc.202002596. Epub 2021 Jan 19.
It still remains challenging to simultaneously achieve high stability, selectivity, and activity in CO reduction. Herein, a dual chainmail-bearing nickel-based catalyst (Ni@NC@NCNT) was fabricated via a solvothermal-evaporation-calcination approach. In situ encapsulated N-doped carbon layers (NCs) and nanotubes (NCNTs) gave a dual protection to the metallic core. The confined space well maintained the local alkaline pH value and suppressed hydrogen evolution. Large surface area and abundant pyridinic N and Ni sites ensured high CO adsorption capacity and strength. Benefitting from these, it delivered a CO faradaic efficiency of 94.1 % and current density of 48.0 mA cm at -0.75 and -1.10 V, respectively. Moreover, the performance remained unchanged after continuous electrolysis for 43 h, far exceeding Ni@NC with single chainmail, Ni@NC/NCNT with Ni@NC sitting on the walls of NCNT, bare NCNT and most state-of-the-art catalysts, demonstrating structural superiority of Ni@NC@NCNT. This work sheds light on designing unique architectures to improve electrochemical performances.
在CO还原反应中同时实现高稳定性、高选择性和高活性仍然具有挑战性。在此,通过溶剂热-蒸发-煅烧法制备了一种带有双链甲胄的镍基催化剂(Ni@NC@NCNT)。原位封装的N掺杂碳层(NCs)和纳米管(NCNTs)对金属核起到了双重保护作用。受限空间很好地维持了局部碱性pH值并抑制了析氢反应。大表面积以及丰富的吡啶型N和Ni位点确保了高CO吸附容量和吸附强度。受益于此,在-0.75 V和-1.10 V时,其CO法拉第效率分别为94.1%和电流密度为48.0 mA cm。此外,连续电解43小时后性能保持不变,远远超过具有单链甲胄的Ni@NC、Ni@NC坐在NCNT壁上的Ni@NC/NCNT、裸NCNT以及大多数最先进的催化剂,证明了Ni@NC@NCNT的结构优越性。这项工作为设计独特结构以改善电化学性能提供了思路。
