析氧
化学
电解
阳极
过电位
臭氧
电解质
电化学
电解水
化学工程
多孔性
氧气
分解水
毛细管作用
电极
无机化学
材料科学
催化作用
复合材料
有机化学
物理化学
光催化
工程类
作者
Chen Zhang,Yingfeng Xu,Ping Lü,Xiaohua Zhang,Fangfang Xu,Jianlin Shi
摘要
A significant overpotential necessary for the electrochemical oxygen evolution reaction (OER) is one of the most serious disadvantages in water electrolysis, which, on the contrary, gives the probability to electrochemically produce ozone alternative to the common corona discharge. To effectively suppress the competitive OER and improve gaseous ozone escaping, here we present a capillary effect-enabled electrolysis strategy by employing an unusual partial-submersed mode of anode composed of a β-PbO2 cuboids-loaded bulk porous Pb, and realize a much enhanced electrocatalytic gaseous ozone production in comparison to the cases of solid Pb counterpart and/or usual submersion operation. Detailed study reveals a capillary pressure-induced “molecular oxygen-locking effect” in the electrolyte fully filled in the porous structure of the electrode area above the electrolyte pool level, which unexpectedly leads to the production of unusual ·O3– intermediate. Distinctive from the traditional electrochemical ozone production (EOP) mechanism dependent on the essential reaction between the atomic oxygen and molecular oxygen, the ·O3– intermediate generation favors the EOP process in the special case where the capillary action is relevant for a porous bulk anode.
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