%0 Journal Article %T 在TiO<sub>2</sub>纳米阵列上电沉积RuO<sub>2</sub>用于CO<sub>2</sub>电还原<br>Electrodeposition of RuO<sub>2</sub> Layers on TiO<sub>2</sub> Nanotube Array toward CO<sub>2</sub> Electroreduction %A 蒋 孛 %A 张莉娜 %A 秦先贤 %A 蔡文斌< %A br> %A Bei Jiang %A Lina Zhang %A Xianxian Qin %A Wenbin Cai %J 电化学 %D 2017 %R 10.13208/j.electrochem.161253 %X 摘要 传统上,RuO2/TiO2复合电极制备是通过在TiO2/Ti基体上多次涂覆含Ru前驱体溶液和随后热分解(TD)来实现的. 为克服上述方法中Ru用量大和利用率低之不足, 本工作主要基于循环伏安法(CV)在TiO2纳米管阵列(TNA)上电沉积RuO2制备RuO2CV/TNA复合电极. SEM、GIXRD和CV结果表明, 电沉积的RuO2为无定型结构, 所制备电极中的Ru用量约为传统的RuO2TD/TNA电极中Ru用量的1/30. 尽管两电极催化CO2还原产物的法拉第效率接近, 但是RuO2CV/TNA电极比RuO2TD/TNA电极展示了更高的还原电流, 较正的初始还原电位和更好的稳定性. 与磷酸盐缓冲溶液中电还原CO2相比,RuO2CV/TNA电极在0.1 mol?L-1 KHCO3中电还原CO2除生成更高法拉第效率的甲酸根和甲烷外,还检测到CO的生成.<br>RuO2/TiO2 composite materials have multitude of electrocatalytic applications including but not limited to CO2 reduction reaction (CO2RR). RuO2/TiO2 electrodes were previously prepared by repetitive coating and thermal decomposition (TD) of a Ru(III) precursor solution on Ti substrate. In this work, electrochemical potential cycling is applied to deposit amorphous RuO2 (α-RuO2) layers onto TiO2 nanotube array (TNA) (RuO2CV/TNA) preformed on Ti foil. SEM, GIXRD, and voltammetry are applied to characterize the structures of the resulting RuO2CV/TNA. Ru loading on the RuO2CV/TNA electrode is ca. 1/30 of that on the conventional RuO2TD/TNA electrode. Although both electrodes yield similar faradaic efficiencies (FEs) for the reduction products, the RuO2CV/TNA electrode displays a much higher reduction current, a more positive initial reduction potential and a better durability than the RuO2TD/TNA one. In addition to higher FEs for formate and CH4, the RuO2CV/TNA electrode yields the product of CO for the CO2RR in 0.1 mo?lL-1 KHCO3, which is not available in a PBS solution with pH 7 %K CO< %K sub> %K 2< %K /sub> %K 还原 %K 无定型RuO< %K sub> %K 2< %K /sub> %K TiO< %K sub> %K 2< %K /sub> %K 纳米阵列 %K 电沉积 %K < %K br> %K CO< %K sub> %K 2< %K /sub> %K reduction %K amorphous RuO< %K sub> %K 2< %K /sub> %K TiO< %K sub> %K 2< %K /sub> %K nanotube array %K electrodeposition %U http://electrochem.xmu.edu.cn/CN/abstract/abstract10383.shtml