污染物
苯酚
水溶液
选择性
废水
吸附
联轴节(管道)
区域选择性
密度泛函理论
间苯二酚
氢氧化物
化学
产量(工程)
膜
工业废水处理
资源回收
间歇式反应器
层流
化学工程
甲烷氧化偶联
组合化学
产物抑制
酚类
工作(物理)
分子
多孔性
污水处理
有机化学
副产品
扩散
水处理
环境修复
反应机理
动力学
作者
Cuiwei Du,Wanyi Fu,Jie Li,Hui Xu,Bingcai Pan
标识
DOI:10.1021/acs.est.5c08457
摘要
Selective transformation of phenol in wastewater into value-added products offers a sustainable strategy for simultaneous pollutant abatement and chemical resource recovery. However, conventional oxidation processes suffer from low product selectivity due to competing pathways, including ring-opening degradation, C-C/C-O coupling, and polymerization. Here, we develop an angstrom-confined flow-through system using laminar membrane nanochannels to enable spatiotemporally controlled oxidation and regioselective C-C coupling. The 6.0 Å interlayer spacing of ZnFe-layered double hydroxide enforces stereoselective alignment of phenoxy radicals, while flow modulation precisely regulates the reaction progression. This enzyme-inspired dual-control strategy achieves 84% C-C selectivity at 50% phenol conversion and suppresses parasitic pathways (C-O coupling, overoxidation) that are endemic to traditional batch systems. Mechanistic studies and density functional theory (DFT) calculations reveal that nanoconfinement thermodynamically stabilizes para-oriented radicals, steering barrierless C-C coupling. Integrated with selective resin adsorption for biphenol harvest and phenol recycling, up to 90% cumulative product yield is achieved. This work establishes a low-carbon pollutant-to-product paradigm for resource recovery from contaminated waters.
科研通智能强力驱动
Strongly Powered by AbleSci AI