单线态氧
催化作用
化学
生物降解
加合物
光化学
共价键
废水
反应速率常数
超分子化学
流出物
化学工程
硼
杠杆
单重态
组合化学
分子
纳米技术
选择性
氧气
催化效率
材料科学
降级(电信)
污染物
污水处理
解聚
反应速率
作者
Tao Zhang,Yi Du,Yihuai Zhang,Yaoqi Liu,Pengfei Wang,Sihui Zhan
摘要
ABSTRACT Selective nonradical oxidation to enhance biodegradability is an attractive route for wastewater pretreatment, but molecular control of peroxymonosulfate (PMS) activation remains elusive. Here we report a Fe‐N 4 catalyst with second‐shell boron coordination (FeN 4 /B) synthesized by supramolecular self‐assembly. The second‐shell B imposes long‐range electronic regulation and cooperative spin alignment, shifting the Fe‐PMS * adduct to a high‐spin configuration and promoting spin‐allowed interfacial charge transfer. Concomitantly, covalent B─H bonding with PMS generates the key SO 5 * intermediate that channels PMS activation toward singlet oxygen. This structural control delivers ≥96% 1 O 2 selectivity with an observed rate constant k obs = 1.64 min −1 , a 1 O 2 production rate of 227 µmol L −1 min −1 , and 98% PMS‐to‐ 1 O 2 conversion. FeN 4 /B rapidly degrades 15 highly biotoxic pollutants within 10 min and retains activity under pH fluctuations, common ion/DOM interference, and across diverse natural waters. Implemented as a hydrogel‐immobilized ALICR‐FeN 4 /B module, the catalyst operated continuously for 168 h, increased effluent biodegradability (BOD/COD > 0.50), reduced acute toxicity, and lowered downstream biological treatment load at an estimated pretreatment cost of ∼$0.14 t −1 . These results establish cooperative spin alignment as a central lever of second‐shell engineering, bridging atomistic design and scalable water treatment to enable practical, economically favorable pretreatment based on selective PMS‐to‐ 1 O 2 conversion.
科研通智能强力驱动
Strongly Powered by AbleSci AI