Constructing an orderly electron transport channel on boron regulated biomass carbon fiber for selective ROS generation and water decontamination

化学 催化作用 人体净化 电子转移 吸附 过硫酸盐 降级(电信) 化学工程 环境化学 光化学 废物管理 有机化学 计算机科学 电信 工程类
作者
Wei Liu,Yingbo Dong,Junfei Liu,Haoxuan Ding,Hai Lin
出处
期刊:Journal of Hazardous Materials [Elsevier BV]
卷期号:464: 132987-132987 被引量:9
标识
DOI:10.1016/j.jhazmat.2023.132987
摘要

Antibiotic pollution has raised widely attention due to the difficult biodegradation and lasting toxicity to public health, metal-free material based heterogeneous catalysis is a highly-promise and eco-friendly technology for organics elimination. Herein, boron doped biomass carbon fiber (B-CF) was synthesized to construct orderly electron transport channels for enhancing catalytic performance and deeply purifying organics polluted water. Integrating systematical quenching experiments and EPR detection, O2·- and 1O2 are found to be dominating reactive oxygen species (ROS) for norfloxacin (NOR) degradation rather than ∙OH or SO4∙-. Adsorption, catalytic degradation in pristine CF/peroxodisulfate (PDS) and B-CF/PDS systems, electrochemical tests, and theory calculations were compared and the results suggested B-CF surface can trigger intense electron transfer via simultaneous activating NOR and PDS, and electrons transferred from NOR to B-CF-PDS compound, resulting in selective and remarkably enhanced ROS generation. Moreover, it was found that B-CF exhibited surprising adsorption capacity for NOR (834.4 mg g-1), and it can also remove SO42- from the solution through electrostatic attraction. This B-CF/PDS system is efficient within a wide operation pH from 3 to 11 and exhibits long lasting activity (> 274 h maintaining over 80% efficiency). This study unveils the highly selective formation of O2-· and 1O2 and solves the short lifetime of catalysts in persulfate-based catalysis, which provides feasible technology for advanced water purification.
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