Efficient Adsorption and Degradation of Tetracycline Hydrochloride Using Metal–Organic Framework-Derived Cobalt-Based Catalysts and Mechanism Insight

IF 3.7 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Langmuir Pub Date : 2024-10-20 DOI:10.1021/acs.langmuir.4c03081

Penghao Gao, Junjie Wang, Jinkai Pan, Shihui Wang, Futang Liu, Mengzhao Li, Xiaole Dong, Wenle Kong, Peiling Gao, Xinpeng Liu

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Abstract

High-performance Co-based catalysts were derived by pyrolysis using synthesized MOFs as self-sacrificial templates. Various catalytic systems were constructed by peroxymonosulfate (PMS) to degrade tetracycline hydrochloride (TC). Adsorption–degradation efficiencies, cycle performance, dynamics, and the adsorption catalytic mechanism of various catalytic systems for TC were studied. The effects of different synthetic solvents, pyrolysis temperatures, and single/bimetallic element compositions on degradation efficiency were innovatively compared. The optimal catalyst and PMS dosage for the experiment were determined to be 10 mg and 0.1 mL, respectively. The results indicated that all catalytic systems could efficiently degrade TC and have a high acid–base resistance. The catalyst activity was significantly influenced by the pyrolysis temperature. The optimum pyrolysis temperatures for Zn@Co-N-C-T, CH₃OH@Co-N-C-T, and H₂O@Co-N-C-T were 1000, 900 and 900 °C, respectively. More abundant pore structures and active sites were generated in Zn@Co-N-C-1000, exhibiting an excellent TC degradation efficiency and adsorption capacity, achieving 94.73% and 167.564 mg/g, respectively. Meanwhile, the total organic carbon (TOC) of TC (50 mL, 50 mg/L) achieved a removal rate (TOC/TOC₀) of 50.28%. Zn@Co-N-C-1000/PMS maintained over 83.27% TC degradation after five cycles. The adsorption mechanism of the catalyst for TC was investigated through the analysis of adsorption kinetics and isotherm models. The quenching test and EPR results indicated that TC was primarily degraded through the nonradical pathway. The efficient degradation of TC is attributed to the rapid electron transfer processes occurring at the two-phase interface and the redox cycling of Co⁰/Co²⁺/Co³⁺. Finally, LC–MS was used to analyze the intermediate products of TC degradation in the Zn@Co-N-C-1000/PMS system, and two degradation pathways were proposed.

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利用金属有机框架衍生的钴基催化剂高效吸附和降解盐酸四环素及其机理探究

利用合成的 MOFs 作为自人工模板，通过热解衍生出高性能 Co 基催化剂。利用过一硫酸盐（PMS）构建了多种催化体系，用于降解盐酸四环素（TC）。研究了各种催化体系对四环素的吸附降解效率、循环性能、动力学和吸附催化机理。创新性地比较了不同合成溶剂、热解温度和单/双金属元素组成对降解效率的影响。实验确定的最佳催化剂和 PMS 用量分别为 10 毫克和 0.1 毫升。结果表明，所有催化体系都能高效降解三氯甲烷，并具有较高的耐酸碱性。催化剂活性受热解温度的影响较大。Zn@Co-N-C-T 、CH3OH@Co-N-C-T 和 H2O@Co-N-C-T 的最佳热解温度分别为 1000、900 和 900 ℃。Zn@Co-N-C-1000产生了更丰富的孔隙结构和活性位点，表现出优异的TC降解效率和吸附容量，分别达到94.73%和167.564 mg/g。同时，对 TC 总有机碳（TOC）（50 mL，50 mg/L）的去除率（TOC/TOC0）达到了 50.28%。Zn@Co-N-C-1000/PMS在五个循环后对 TC 的降解率保持在 83.27% 以上。通过吸附动力学和等温线模型分析，研究了催化剂对 TC 的吸附机理。淬灭试验和 EPR 结果表明，TC 主要通过非自由基途径降解。TC 的高效降解归因于两相界面上发生的快速电子转移过程以及 Co0/Co2+/Co3+ 的氧化还原循环。最后，利用 LC-MS 分析了 Zn@Co-N-C-1000/PMS 系统中 TC 降解的中间产物，并提出了两种降解途径。

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来源期刊

Langmuir 化学-材料科学：综合

CiteScore

6.50

自引率

10.30%

发文量

1464

审稿时长

2.1 months

期刊介绍： Langmuir is an interdisciplinary journal publishing articles in the following subject categories: Colloids: surfactants and self-assembly, dispersions, emulsions, foams Interfaces: adsorption, reactions, films, forces Biological Interfaces: biocolloids, biomolecular and biomimetic materials Materials: nano- and mesostructured materials, polymers, gels, liquid crystals Electrochemistry: interfacial charge transfer, charge transport, electrocatalysis, electrokinetic phenomena, bioelectrochemistry Devices and Applications: sensors, fluidics, patterning, catalysis, photonic crystals However, when high-impact, original work is submitted that does not fit within the above categories, decisions to accept or decline such papers will be based on one criteria: What Would Irving Do? Langmuir ranks #2 in citations out of 136 journals in the category of Physical Chemistry with 113,157 total citations. The journal received an Impact Factor of 4.384*. This journal is also indexed in the categories of Materials Science (ranked #1) and Multidisciplinary Chemistry (ranked #5).