尿素和氟化铵二氮与铜和铁双金属共掺杂碳毡作为阴极用于诺氟沙星的电-芬顿降解:1O2主导的氧化途径

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Jing Li, Lili Gao, Yue Chen, Xinyi Meng, Xuelian Li, Kai Qi and Jiandong Zhang
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引用次数: 0

摘要

同时掺杂金属和非金属杂原子的碳材料已成为异相电-芬顿技术和去除难处理有机物催化剂的重要研究对象。然而,目前仍缺乏对碳中掺杂多种氮源及其可能的协同机制的深入研究。本研究设计了两种氮源(尿素和氟化铵)和 Cu&Fe 双金属共掺杂碳毡电极(C-CuFe/N),以探讨共掺杂对碳的影响。C-CuFe/N 对诺氟沙星的降解效率高(97.2%),离子浸出率低,循环稳定性高(10 次循环后为 90.3%),优于不掺氮或只掺氮的 C-CuFe、C-CuFe/UN 和 C-CuFe/FN。各种表征表明,C-CuFe/N 具有最大的比表面积、最高的铁(II)含量、最多的表面氧和活性位点,重要的是具有稳定的 M-Nx 键,这表明 UN 和 FN 具有极佳的协同效应。根据淬灭实验,C-CuFe、C-CuFe/UN 和 C-CuFe/FN 的主要活性氧为自由基(-OH 和 O2˙-),而 C-CuFe/N 在酸性条件下则转变为非自由基(1O2)。另外,C-CuFe/N 在较宽的初始 pH 值范围(1.2-11.3)内表现出良好的催化性能(97.2-92.3%),但在降解过程中,所有 pH 值均向中性转变,氧化途径也从酸性条件下的 1O2 主导转变为中性或碱性条件下的自由基主导。总体而言,双硝基之间存在着良好的协同效应,既提高了催化剂的催化活性,又增强了催化剂的稳定性,从而为催化剂的设计提供了一种良好的策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Urea and ammonium fluoride di-nitrogen and Cu & Fe bi-metal co-doped carbon felt as cathode for electro-Fenton degradation of norfloxacin: 1O2-dominated oxidation pathway†

Urea and ammonium fluoride di-nitrogen and Cu & Fe bi-metal co-doped carbon felt as cathode for electro-Fenton degradation of norfloxacin: 1O2-dominated oxidation pathway†

Urea and ammonium fluoride di-nitrogen and Cu & Fe bi-metal co-doped carbon felt as cathode for electro-Fenton degradation of norfloxacin: 1O2-dominated oxidation pathway†

Carbon materials co-doped with both metals and non-metallic heteroatoms have become an important research focus as catalysts for heterogeneous electro-Fenton technology and the removal of refractory organics. However, there is still a lack of in-depth studies on the doping of carbon with multiple nitrogen sources and their possible synergistic mechanism. In this study, two types of nitrogens (urea and ammonium fluoride) and Cu&Fe bimetal co-doped carbon felt electrodes (C–CuFe/N) were designed to explore the effect of co-doping on carbon. C–CuFe/N exhibited a high degradation efficiency towards norfloxacin (97.2%), low ion leaching and high cycling stability (90.3% after ten cycles), better than those shown by C–CuFe, C–CuFe/UN and C–CuFe/FN prepared with none or a single nitrogen dopant. Various characterizations indicated that C–CuFe/N has the largest specific surface area, highest content of Fe(II), most surface oxygen and active sites, and importantly, stable M–Nx bond, indicating that UN and FN exhibited an excellent synergistic effect. According to the quenching experiments, the dominant reactive oxygen species for C–CuFe, C–CuFe/UN and C–CuFe/FN were radical species (·OH and O2˙), while they changed to non-radical species (1O2) for C–CuFe/N under acidic condition. Alternatively, C–CuFe/N showed a good catalytic performance (97.2–92.3%) over a wide initial pH range (1.2–11.3), but during the degradation process, all the pH values changed toward neutral, and the oxidation pathway varied from 1O2-dominated under acidic condition to radical-dominated under neutral or alkaline condition. Generally, a good synergistic effect was found to exist between the dual nitrogens, which promoted the catalytic activity as well as stability of the catalyst, thus providing a good strategy to design catalysts.

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