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Creating and tailoring ultrathin two-dimensional uranyl-organic framework nanosheets for boosting photocatalytic oxidation reactions

For the first time, we employ a proof-of-concept weak supramolecular-interactions strategy to construct ultrathin uranyl-organic framework nanosheets, which exhibit significantly enhanced photocatalytical activity compared to their bulk counterparts. [Display omitted] •A proof-of-concept weak supram...

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Published in:Applied catalysis. B, Environmental Environmental, 2021-11, Vol.297, p.120485, Article 120485
Main Authors: Gao, Zhi, Lai, Yulian, Tao, Yuan, Xiao, Longhui, Li, Zhuyao, Zhang, Liuxin, Sun, Lijun, Luo, Feng
Format: Article
Language:English
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Summary:For the first time, we employ a proof-of-concept weak supramolecular-interactions strategy to construct ultrathin uranyl-organic framework nanosheets, which exhibit significantly enhanced photocatalytical activity compared to their bulk counterparts. [Display omitted] •A proof-of-concept weak supramolecular-interactions strategy was proposed to construct ultrathin uranyl-organic framework nanosheets.•The thickness of the resulted nanosheets is extremely thin down to only 1 nm.•The ultrathin nanosheet samples present significantly enhanced photocatalytic oxidation activity compared to their pristine counterpart. The fabrication of ultrathin MOFs nanosheets (just single- or few-layer) is highly desired but seriously restricted by the relatively strong interactions between layers in layered MOFs precursors. Herein, for the first time, we employ a proof-of-concept weak supramolecular-interactions strategy to construct ultrathin uranyl-organic framework nanosheets. Impressively, the thickness of the resulting nanosheets is extremely thin down to only 1 nm, just equal to two layers, and also shows high dependence on the stacking mode of 2D uranyl MOFs precursors, for example, two layers in the eclipsed stacking mode vs. eight layers in the staggered stacking mode. Most importantly, this would significantly tailor their optical and electronic properties. As a result, the ultrathin nanosheet samples (two layers) present significantly enhanced photocatalytic oxidation activity compared to their pristine counterpart (4.5 times) and another nanosheet sample (eight layers, 2.2-fold). This work may open up a gate toward ultrathin uranyl-organic nanosheet for advanced functions.
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2021.120485