Revelation of the photoexcitation mechanism of COF-DFB materials based on first principles

IF 3.4 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Reaction Chemistry & Engineering Pub Date : 2025-01-17 DOI:10.1039/D4RE00492B

Huanjun Su, Yumeng Zhang, Weili Shi, Haoyang Shi, Yani Liu and Ying Lin

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Abstract

A two-dimensional covalent organic framework (COF) material successfully prepared in the experiment exhibits good light absorption performance, but its internal mechanism is still unclear. A deep understanding of the excitation mechanism of COF materials is of great significance for the preparation and modification of two-dimensional materials. First, the geometric structure of COF-DFB was determined using first-principles and quantum chemical methods, revealing a pore size of 11.62 Å. Secondly, the electron–hole distribution of each excited state of COF-DFB with an oscillator strength greater than 0.1 was further analyzed. It was found that in most excited states of COF-DFB, the electrons are mainly distributed on the TMBP monomer, while the holes are concentrated between TMBP (2,2′,6,6′-tetramethyl-4,4′-bipyridine) and DFB (1,4-diformylbenzene). Finally, the UV-visible spectrum of COF-DFB shows that its maximum absorption wavelength is 413.8 nm. These results indicate that COF-DFB possesses excellent photoelectric properties and demonstrates significant application potential in the field of photocatalysis.

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基于第一性原理的COF-DFB材料光激发机理的揭示

实验成功制备的二维共价有机骨架（COF）材料具有良好的光吸收性能，但其内部机理尚不清楚。深入了解COF材料的激发机理对二维材料的制备和改性具有重要意义。首先，利用第一性原理和量子化学方法确定了COF-DFB的几何结构，发现其孔径为11.62 Å。其次，进一步分析了振子强度大于0.1的COF-DFB各激发态的电子空穴分布。结果发现，在COF-DFB的大多数激发态中，电子主要分布在TMBP单体上，空穴集中在TMBP（2,2 ',6,6 ' -四甲基-4,4 ' -联吡啶）和DFB（1,4-二甲基苯）之间。最后，COF-DFB的紫外可见光谱显示其最大吸收波长为413.8 nm。这些结果表明，COF-DFB具有优异的光电性能，在光催化领域具有重要的应用潜力。

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来源期刊

Reaction Chemistry & Engineering Chemistry-Chemistry (miscellaneous)

CiteScore

6.60

自引率

7.70%

发文量

227

期刊介绍： Reaction Chemistry & Engineering is a new journal reporting cutting edge research into all aspects of making molecules for the benefit of fundamental research, applied processes and wider society. From fundamental, molecular-level chemistry to large scale chemical production, Reaction Chemistry & Engineering brings together communities of chemists and chemical engineers working to ensure the crucial role of reaction chemistry in today’s world.