基于咪唑功能化Ba(II)-MOF材料荧光检测氟啶胺和苦味酸的研究-化学与化工研究-CSCIED科技核心评价数据库-手机版

基于咪唑功能化Ba(II)-MOF材料荧光检测氟啶胺和苦味酸的研究

Study on fluorescence detection of fluazinam and picric acid based on imidazole-functional Ba(II)-MOF

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DOI	10.12208/j.jccr.20240002
刊名	化学与化工研究 Journal of Chemistry and Chemical Research
年，卷(期)	2024, 4(1)
作者	毛欣怡*,李盼盼,陈俏霞,吕依诺,刘昕语,辛雪莲,
作者单位	河北大学公共卫生学院河北省公共卫生安全重点实验室河北保定 ;
摘要	氟啶胺（Fluazinam, FLU）和苦味酸（picric acid, PA）是两种典型的有机化合物，具有高毒性和生物蓄积性，会造成环境污染，影响人体健康。本文基于课题组前期研究参照文献制备了咪唑功能化材料HBU-167（Ba(II)-MOF），并将其应用于荧光检测氟啶胺和苦味酸。在氟啶胺检测方面，其检出限（Limit of Detection, LOD）为7.5 μM，当氟啶胺的浓度增加到909 μM时，荧光猝灭率达到95.65％，通过Stern-Volmer方程计算得到猝灭常数为22.00 M−1；通过紫外-可见光谱法等检测手段，推测其检测机理为动态荧光猝灭，HBU-167与氟啶胺之间存在竞争吸收。在苦味酸检测方面，其LOD为0.46 μM，当苦味酸的浓度增加到56.604 μM时，通过Stern-Volmer方程计算得到猝灭常数为4.2 × 104 M−1；通过荧光寿命及荧光量子产率、吸附能和紫外-可见光谱等检测手段，推测其检测机理为静态荧光猝灭。
Abstract	Fluazinam (FLU) and picric acid (PA) are two typical organic compounds with high toxicity and bioaccumulation, which will cause environmental pollution and affect human health. In this paper, imidazole functional material HBU-167 (Ba(II)-MOF) was prepared based on the previous research references of our research group, and it was applied to the fluorescence detection of fluridine and picric acid. For the Detection of fluridine, the Limit of Detection (LOD) was 7.5 μM. When the concentration of fluridine increased to 909 μM, the fluorescence quenching rate reached 95.65%, and the quenching constant was 22.00 M−1 calculated by Stern-Volmer equation. Through UV-VIS spectroscopy and other detection methods, it is speculated that the detection mechanism is dynamic fluorescence quenching, and there is competitive absorption between HBU-167 and fluridine. In the detection of picric acid, the LOD is 0.46 μM, and when the concentration of picric acid increases to 56.604 μM, the quenching constant calculated by Stern-Volmer equation is 4.2 × 104 M−1. By means of fluorescence lifetime, fluorescence quantum yield, adsorption energy and UV-VIS spectrum, the detection mechanism is inferred to be static fluorescence quenching.
关键词	金属有机框架；氟啶胺；荧光测定实验；苦味酸；快速检测
KeyWord	Metal-organic framework; Fluridine; Fluorescence assay experiment; Picric acid; Rapid detection
基金项目
页码	5-15

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引用本文

毛欣怡*,李盼盼,陈俏霞,吕依诺,刘昕语,辛雪莲. 基于咪唑功能化Ba(II)-MOF材料荧光检测氟啶胺和苦味酸的研究 [J]. 化学与化工研究. 2024; 4; (1). 5 - 15.

文献评论

冯**香港理工****** 已认证✔

2025-12-18 12:55:52

该论文围绕咪唑功能化 Ba(II)-MOF（HBU-167）的构筑及其在有机污染物检测中的应用开展了系统研究，选题具有明确的环境与分析化学背景意义。作者通过多种结构与光谱表征手段，验证了材料良好的结晶性、稳定性与荧光性能，并分别针对氟啶胺和苦味酸构建了荧光检测与荧光比色检测体系，系统评估了其灵敏度、选择性和抗干扰能力。研究进一步结合 PXRD、UV–Vis、荧光寿命测试及 DFT 计算，对不同分析物对应的动态/静态荧光猝灭机理进行了较为深入的探讨，逻辑清晰、数据完整。整体而言，该工作实验设计合理，结果可信，为 MOF 材料在环境有机污染物快速检测领域的应用提供了有价值的实验依据和理论支撑，具有一定的学术参考价值和应用潜力。

程**天津**** 已认证✔

2025-12-03 11:34:36

该论文围绕咪唑功能化 Ba(II)-MOF（HBU-167）构建的荧光传感体系展开研究，系统评估了其对氟啶胺和苦味酸的检测性能，并结合光谱表征、PXRD、DFT 计算等手段深入探讨了猝灭机理。文章结构清晰、实验设计较为完整，结果数据能够有力支撑检测性能和识别机制的结论。HBU-167 在两类典型有机污染物检测中的选择性、灵敏度与抗干扰表现突出，显示出一定的应用潜力。论文在创新性阐述、图表精炼度以及讨论部分的逻辑串联上仍有提升空间。

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