材料科学
催化作用
光催化
复合数
浸出(土壤学)
环境友好型
化学工程
纳米技术
金属有机骨架
废水
金属
微球
多相催化
环境污染
萃取(化学)
过程(计算)
工业废水处理
工作(物理)
可重用性
作者
Xiaoliang Li,Zeyang Yu,Ning Wu,Yue Sun,Xiang Chen,Xiang Chen,Yue Zhang,Siyao Qin,Xu-cong Wang,Hao Gong,Zifei Meng,Morten Willatzen,Ning Li,Zhong Lin Wang,Zhenfeng Bian,Xiangyu Chen,Xiangyu Chen
标识
DOI:10.1002/adma.202514244
摘要
Abstract Precious metal recovery has become increasingly critical due to resource scarcity, while conventional extraction methods often suffer from low efficiency and pollution problem. Here, this work proposes an efficient and environmentally friendly catalytic strategy based on the integration of contact‐electro‐catalysis (CEC) and photocatalysis. The composite microsphere catalyst is fabricated by using low temperature co‐firing TiO 2 /PTFE particles, which have an average diameter of ≈10 µm and expose both TiO 2 and PTFE active sites on its surface, enabling dual CEC–photocatalytic synergy reactions. Compared to pristine TiO 2 catalyst with similar weight, this composite microsphere catalyst exhibits a tenfold enhancement in gold extraction efficiency from electronic waste. This high‐performance leaching system operates under mild conditions, alleviating the need for traditional strong oxidants and offering potential for industrial application. Density functional theory (DFT) calculations further reveal that charge transfer from H 2 O to PTFE and subsequently into TiO 2 , with favorable energy band alignment between PTFE and TiO 2 ensuring efficient carrier hopping and enhanced photocatalytic activity. This composite catalytic strategy based on organic–inorganic microsphere catalysts may be extended to areas like wastewater treatment, organic synthesis, and industrial waste valorization.
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