Acetylacetone Boosts the Photocatalytic Activity of Metal–Organic Frameworks by Tunable Modification

Catalysts Pub Date : 2024-06-05 DOI:10.3390/catal14060367

K. Wei, Jianghua Yang, Shuangshuang Wei, Hongcen Zheng, Shujuan Zhang

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Abstract

Typical metal–organic frameworks (MOFs) usually suffer from a limited visible light-trapping ability and easy recombination of charge carriers, hindering their photocatalytic applications. Acetylacetone (AA), leveraging its exceptional coordination capabilities, serves as a versatile and effective modifier for enhancing the photocatalytic activity of MOFs via a post-synthesis approach. The synthesis of diketone-anchored MOFs with AA can be achieved by first diazotizing the amino groups on the ligands of MOFs, followed by a condensation reaction between AA and the resulting azide. Gradient AA loadings ranging from 17% to 98% were obtained, showcasing the tunability of this approach. Interestingly, a sub-stoichiometric effect was exhibited between the AA loading and the visible photocatalytic performance of the modified photocatalyst. The singlet oxygen yields of MIL-125-AA-37% and MIL-125-AA-54% were about 1.3 times that of MIL-125-AA-17% and 3.0 times that of MIL-125-AA-98%. The improved photocatalytic activity could be attributed to the fact that the AA modification altered the electron density of the Ti metal center, leading to the creation of a significant amount of oxygen defects. This alteration resulted in a reduction in the recombination of charge carriers and thus a better charge separation. In short, AA modification provides a new strategy to maximize the visible photocatalytic performance of MOFs.

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乙酰丙酮通过可调修饰提高金属有机框架的光催化活性

典型的金属有机框架（MOFs）通常存在可见光捕获能力有限和电荷载流子容易重组的问题，从而阻碍了它们的光催化应用。乙酰丙酮（AA）利用其优异的配位能力，可作为一种多功能、有效的改性剂，通过合成后方法提高 MOF 的光催化活性。首先将 MOF 配体上的氨基重氮化，然后在 AA 与生成的叠氮化物之间进行缩合反应，就能合成含有 AA 的二酮锚定 MOF。研究人员获得了从 17% 到 98% 不等的梯度 AA 负载，展示了这种方法的可调性。有趣的是，AA 负载与改性光催化剂的可见光光催化性能之间呈现出亚化学计量效应。MIL-125-AA-37% 和 MIL-125-AA-54% 的单线态氧产率分别是 MIL-125-AA-17% 和 MIL-125-AA-98% 的 1.3 倍和 3.0 倍。光催化活性的提高可归因于 AA 改性改变了 Ti 金属中心的电子密度，从而产生了大量的氧缺陷。这种改变减少了电荷载流子的重组，从而提高了电荷分离效果。简而言之，AA 修饰为最大限度地提高 MOFs 的可见光光催化性能提供了一种新策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Catalysts

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