Nano Silica Catalyzed Synthesis, NMR Spectral and Photophysical Studies of Imidazole Derivatives

IF 2.8 3区材料科学 Q3 CHEMISTRY, PHYSICAL Silicon Pub Date : 2024-10-15 DOI:10.1007/s12633-024-03176-5

T. S. Rajasekar, N. Srinivasan, K. Jayamoorthy

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Abstract

This study explores the use of nano SiO₂ as a catalyst in the synthesis of imidazole derivatives, demonstrating its superior catalytic efficiency compared to conventional catalysts. The high surface area of nano SiO₂ significantly enhances reactant interactions, resulting in higher yields of imidazole products. Detailed NMR spectral analysis provided precise characterizations of the imidazole derivatives, revealing well-defined chemical shifts. The influence of solvent polarity on absorption and fluorescence spectra was investigated, showing that polar solvents induce pronounced bathochromic shifts by stabilizing the excited states through hydrogen bonding and dipole interactions. Quantum yield and emission kinetics analyses highlighted the role of non-radiative decay pathways in reducing fluorescence efficiency. Furthermore, DFT calculations of HOMO–LUMO energies elucidated how substituents affect electronic transitions and solvatochromic shifts. These findings underscore the effectiveness of nano SiO₂ as a catalyst, illustrate the impact of solvent interactions on molecular behavior, and provide comprehensive insights into the electronic properties of imidazole derivatives, offering valuable implications for both research and practical applications.

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纳米二氧化硅催化咪唑衍生物的合成、核磁共振波谱和光物理研究

本研究探讨了纳米二氧化硅作为催化剂在咪唑衍生物合成中的应用，证明其催化效率优于传统催化剂。纳米二氧化硅的高比表面积显著增强了反应物之间的相互作用，从而提高了咪唑产品的产量。详细的核磁共振光谱分析提供了咪唑衍生物的精确特征，揭示了明确的化学位移。研究还探讨了溶剂极性对吸收和荧光光谱的影响，结果表明极性溶剂通过氢键和偶极相互作用稳定激发态，从而引起明显的浴色偏移。量子产率和发射动力学分析强调了非辐射衰变途径在降低荧光效率方面的作用。此外，对 HOMO-LUMO 能量的 DFT 计算阐明了取代基如何影响电子跃迁和溶解变色。这些发现强调了纳米二氧化硅作为催化剂的有效性，说明了溶剂相互作用对分子行为的影响，并提供了对咪唑衍生物电子特性的全面见解，为研究和实际应用提供了宝贵的启示。

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来源期刊

Silicon CHEMISTRY, PHYSICAL-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

5.90

自引率

20.60%

发文量

685

审稿时长

>12 weeks

期刊介绍： The journal Silicon is intended to serve all those involved in studying the role of silicon as an enabling element in materials science. There are no restrictions on disciplinary boundaries provided the focus is on silicon-based materials or adds significantly to the understanding of such materials. Accordingly, such contributions are welcome in the areas of inorganic and organic chemistry, physics, biology, engineering, nanoscience, environmental science, electronics and optoelectronics, and modeling and theory. Relevant silicon-based materials include, but are not limited to, semiconductors, polymers, composites, ceramics, glasses, coatings, resins, composites, small molecules, and thin films.