A polymer tethering strategy to achieve high metal loading on catalysts for Fenton reactions

The development of heterogenous catalysts based on the synthesis of 2D carbon-supported metal nanocatalysts with high metal loading and dispersion is important. However, such practices remain challenging to develop. Here, we report a self-polymerization confinement strategy to fabricate a series of...

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Published in:Nature communications 2023-11, Vol.14 (1), p.7841-7841, Article 7841
Main Authors: Wang, Lixin, Rao, Longjun, Ran, Maoxi, Shentu, Qikai, Wu, Zenglong, Song, Wenkai, Zhang, Ziwei, Li, Hao, Yao, Yuyuan, Lv, Weiyang, Xing, Mingyang
Format: Article
Language:English
Subjects:
140/146
147/135
147/143
639/301/299
639/638/298
704/172/169/896
Carbon
Catalysts
Catalytic activity
Catechol
Chemical synthesis
Confinement
Dispersion
Electron density
Fabrication
Humanities and Social Sciences
Hydrogen peroxide
Iron
Metal ions
Metals
multidisciplinary
Nanocrystals
Polymerization
Polymers
Science
Science (multidisciplinary)
Sulfamethoxazole
Tethering
Ultrafines
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Summary:The development of heterogenous catalysts based on the synthesis of 2D carbon-supported metal nanocatalysts with high metal loading and dispersion is important. However, such practices remain challenging to develop. Here, we report a self-polymerization confinement strategy to fabricate a series of ultrafine metal embedded N-doped carbon nanosheets (M@N-C) with loadings of up to 30 wt%. Systematic investigation confirms that abundant catechol groups for anchoring metal ions and entangled polymer networks with the stable coordinate environment are essential for realizing high-loading M@N-C catalysts. As a demonstration, Fe@N-C exhibits the dual high-efficiency performance in Fenton reaction with both impressive catalytic activity (0.818 min −1 ) and H 2 O 2 utilization efficiency (84.1%) using sulfamethoxazole as the probe, which has not yet been achieved simultaneously. Theoretical calculations reveal that the abundant Fe nanocrystals increase the electron density of the N-doped carbon frameworks, thereby facilitating the continuous generation of long-lasting surface-bound • OH through lowering the energy barrier for H 2 O 2 activation. This facile and universal strategy paves the way for the fabrication of diverse high-loading heterogeneous catalysts for broad applications. This work reports a self-polymerization confinement strategy to develop and synthesize carbon-supported metal catalysts with high metal loading. Efficient Fenton reactivity is observed for samples containing well dispersed iron sites.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-023-43678-1