肉眼
荧光
离子
化学
滴定法
检出限
水溶液中的金属离子
化学计量学
分析化学(期刊)
丁香酚
质子核磁共振
选择性
光化学
无机化学
色谱法
物理化学
立体化学
光学
生物化学
有机化学
物理
催化作用
作者
M. Jyothi Priya,H. D. Revanasiddappa,B. Jayalakshmi,Ananda Swamynayaka,M. Mahendra,Muzaffar Iqbal,Chandan Shivamallu,Kasim Sakran Abass,Raghavendra G. Amachawadi,Ekaterina Silina,Victor Stupin,Shiva Prasad Kollur
标识
DOI:10.1038/s41598-025-14725-2
摘要
A simple and robust colorimetric and fluorescent eugenol-based chemical sensor, namely, (E)-N'-(5-allyl-2-hydroxy-3-methoxybenzylidene)-2-hydroxybenzohydrazide (EABH) was synthesized and characterized using spectroscopic techniques such as, NMR (1H and 13C) and mass spectra. The chemosensor shows dual behavior for the colorimetric detection of Fe2+ and fluorometric detection of Pb2+ ions with high sensitivity and selectivity towards both the ions. The EABH detects Fe2+ by "naked eye" color change from lime yellow to brown and displayed fluorescence "Turn-off" response to Pb2+ ion. The binding stoichiometry of EABH based on absorption (for Fe2+) and fluorescence (for Pb2+) data along with mass spectral studies indicated 1:2 binding of metal to EABH ratio, which is further verified by Job's plot measurement. Furthermore, the detection limits for Fe2+ and Pb2+ ions were found to be 0.166 µM and 0.095 µM, respectively proving its promising sensitivity. On the other hand, live cell imaging experiments showed that EABH has capability of penetrating through the cell membrane and exhibit significant response to the intracellular interactions when Fe2+ and Pb2+ are introduced in living cells, which reveals its effectiveness in the bioimaging applications. Furthermore, the fabricated chemical sensor EABH was successfully employed for cotton swab and test-paper applications. It is noteworthy that the developed sensor for the detection of Fe2+ and Pb2+ using colorimetric and fluorimetric assays acts as a reliable, cost-effective method compared to other conventional methods. In addition, computational studies such as Frontier Molecular Orbitals (FMOs) and Molecular Electrostatic Potential (MEP) provided a significant information on the interaction sites within EABH, giving profound insights about the chemical reactivity and various physical parameters.
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