Cu Nanowire Networks with Well-Defined Geometrical Parameters for Catalytic Electrochemical CO<sub>2</sub> Reduction
Nils Ulrich, M.R. Schafer, Melina Römer, Sascha Dominic Straub, Siyuan Zhang, Joachim Brötz, C. Trautmann, Christina Scheu, Bastian J. M. Etzold, María Eugenia Toimil‐Molares
Abstract
Three-dimensional, highly interconnected copper nanowire networks are designed and fabricated by electrodeposition in etched ion track polymer templates with interconnected nanochannels and subsequently applied as a catalyst for the electrochemical CO 2 reduction toward hydrocarbons and alcohols in an aqueous electrolyte. The specific surface area expressed by the nanowire networks can be adjusted by tailoring the wire length, wire diameter, and nanowire number density to values between 70 cm 2 and 300 cm 2 per cm 2 geometrical sample area. The conversion efficiency and selectivity of CO 2 reduction toward liquid- and gas-phase products are studied as a function of the applied potential. Before and after the CO 2 reduction reaction, the nanowire networks are characterized by scanning and transmission electron microscopy and by X-ray diffraction, evidencing their stability during CO 2 reduction in a potential region between −0.5 V and −0.93 V versus RHE.