3D 打印智造石墨烯基电极：高效磷回收与资源化处理污水

This project utilizes 3D printing technology to intelligently manufacture three-dimensional graphene-based phosphorus selective electrode materials, achieving efficient phosphorus resource recovery based on electrochemical enhancement technology for the secondary effluent of wastewater treatment plants. The project involves the fields of material chemistry, intelligent manufacturing, physical chemistry, and electrochemistry. Scientific issues such as phosphorus selectivity sensitivity, adsorption-desorption mechanism, and process adaptation and regulation have become important aspects to promote the development of this technology. Focusing on deep wastewater treatment to improve effluent water quality while constructing a phosphorus loss control system, this project explores the optimization of electrode micro-interface conditions and channels using 3D printing technology to further improve mass transfer efficiency and electrochemical performance. By loading metal oxides with phosphorus selectivity modification while improving pseudocapacitance properties and phosphorus recovery efficiency, the project aims to systematically study the functional development of high-performance carbon material carriers with modern intelligent manufacturing technology, and to construct three-dimensional graphene-based electrodes with phosphorus selectivity, which has important scientific value and practical significance in promoting the deep treatment of wastewater phosphorus recovery based on electrochemical enhancement. At the same time, it provides theoretical and scientific basis for the artificial construction of phosphorus cycling, the blocking of phosphorus loss, and the synchronous resource recovery system for high value-added products in wastewater treatment.