In situ generation and efficient activation of H2O2 for pollutant degradation over CoMoS2 nanosphere-embedded rGO nanosheets and its interfacial reaction mechanism

[Display omitted] •MoSC and MoOCo electron transfer bridges are successfully constructed on CMS-rGO NSs.•CMS-rGO NSs possesses the function of generating and activating H2O2 synchronously.•CMS-rGO NSs shows very high Fenton-like activity for degradation of pollutants.•Dye pollutants can directly act...

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Bibliographic Details
Published in:Journal of colloid and interface science 2019-05, Vol.543, p.214-224
Main Authors: Han, Muen, Lyu, Lai, Huang, Yinmei, Liang, Junrong, Xue, Meimei, Wu, Tao, Li, Jiayi, Chen, Meiping, Hu, Chun
Format: Article
Language:English
Subjects:
Fenton reaction
H2O2 generation
Interfacial reaction mechanism
MoS2
Water treatment
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Summary:[Display omitted] •MoSC and MoOCo electron transfer bridges are successfully constructed on CMS-rGO NSs.•CMS-rGO NSs possesses the function of generating and activating H2O2 synchronously.•CMS-rGO NSs shows very high Fenton-like activity for degradation of pollutants.•Dye pollutants can directly act as electron donors for CMS-rGO NSs. Consumption of additional H2O2 is necessary in classical Fenton catalysis. Herein, we report a novel and special nanocatalyst consisting of CoMoS2 nanosphere-embedded, reduced graphene oxide (rGO) nanosheets (CMS-rGO NSs). This nanocatalyst was discovered to have an impressive reactivity for in situ generation and synchronistical activation of H2O2 in different active centers, yielding fast and efficient degradation of the pollutants. The reaction rate is ∼21 times higher than that of conventional Fenton catalysts. The characterization shows that countless flower-like CoMoS2 nanospheres are uniformly embedded in the rGO nanosheets through MoSC bonding bridges in CMS-rGO NSs, which leads to activation of the π electrons and their transfer from rGO to the metal centers (π → M). The formed MoOCo further leads to a distribution of orientations of the electrons around the metal centers due to the different electronegativity of Mo and Co. During the reaction, the dissolved O2 is efficiently reduced to HO2/O2− around the electron-rich Mo center, and HO2/O2− is further reduced to H2O2 around the Co center. The generated H2O2 is finally reduced to OH for degrading dyes in the electron-rich metal (Mo or Co) centers of CMS-rGO NSs. The dye pollutants also act as electron donors, and they are directly degraded in the electron-poor π-center of CMS-rGO NSs, which promote the electron transfer cycle and achieve electron gain-loss balance. This discovery provides a new strategy for H2O2 generation-activation and pollutant degradation through constructing electron transfer bridges over the surface of catalysts.
ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2019.02.062