石墨烯
材料科学
电极
电化学
纳米技术
化学工程
工作电极
扫描电子显微镜
复合材料
化学
工程类
物理化学
作者
Saltanat Toleukhanova,Tzu‐Hsien Shen,Chen Chang,S. Swathilakshmi,Tecla Bottinelli Montandon,Vasiliki Tileli
标识
DOI:10.1002/adma.202311133
摘要
Abstract The ability to resolve the dynamic evolution of electrocatalytically induced processes with electrochemical liquid‐phase electron microscopy (EM) is limited by the microcell configuration. Herein, a free‐standing tri‐layer graphene is integrated as a membrane and electrode material into the electrochemical chip and its suitability as a substrate electrode at the high cathodic potentials required for CO 2 electroreduction (CO 2 ER) is evaluated. The three‐layer stacked graphene is transferred onto an in‐house fabricated single‐working electrode chip for use with bulk‐like reference and counter electrodes to facilitate evaluation of its effectiveness. Electrochemical measurements show that the graphene working electrode exhibits a wider inert cathodic potential range than the conventional glassy carbon electrode while achieving good charge transfer properties for nanocatalytic redox reactions. Operando scanning electron microscopy studies clearly demonstrate the improvement in spatial resolution but reveal a synergistic effect of the electron beam and the applied potential that limits the stability time window of the graphene‐based electrochemical chip. By optimizing the operating conditions, in situ monitoring of Cu nanocube degradation is achieved at the CO 2 ER potential of −1.1 V versus RHE. Thus, this improved microcell configuration allows EM observation of catalytic processes at potentials relevant to real systems.
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