Synthesis of Polystyrene Microsphere-Supported Ag-Ni-Alloyed Catalysts with Core-Shell Structures for Electrocatalytic Performance

Rationally designed synthesis strategy for well-defined morphology which can endow the catalysts with unexpectedly enhanced catalytic properties remains a significant challenge in heterogeneous catalytic reactions. Hence, here we report a facile and controllable synthesis of polystyrene microsphere-...

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Bibliographic Details
Published inPolymer-plastics technology and engineering Vol. 57; no. 9; pp. 875 - 883
Main Authors Yu, Yue, Luan, Dongxue, Bi, Changlong, Ma, Yu, Chen, Yongheng, Zhao, Dongyu
Format Journal Article
LanguageEnglish
Published New York Taylor & Francis 13.06.2018
Taylor & Francis Ltd
Subjects
Catalysis
Catalysts
Chemical reduction
Chemical synthesis
Controllability
Core-shell structure
Electrocatalysts
electrocatalytic
Liquid phases
Microspheres
Morphology
Nickel base alloys
Nitrophenol
oxygen reduction reaction
Oxygen reduction reactions
p-nitrophenol
Performance degradation
Polystyrene resins
Shells
Silver base alloys
Sulfuric acid
surface functionalized
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Summary:Rationally designed synthesis strategy for well-defined morphology which can endow the catalysts with unexpectedly enhanced catalytic properties remains a significant challenge in heterogeneous catalytic reactions. Hence, here we report a facile and controllable synthesis of polystyrene microsphere-supported Ag-Ni-alloyed catalysts (PS@Ag-Ni) with uniform core-shell structures through sulfonated treatment coupled with the subsequent liquid-phase reduction strategy. In this typical synthesis, sulfuric acid acts as the bifunctional roles in directing the core-shell morphology and the linker between the polystyrene microspheres and Ag-Ni alloy. The as-obtained PS@Ag-Ni optimized by tuning in a mass ratio of 1:1 shows superior oxygen reduction reaction activity and electrocatalytic performance toward the degradation of p-nitrophenol in comparison with other range of polystyrene microspheres and Ag-Ni alloy feeding ratios. The superior electrocatalytic and oxygen reduction reaction activity are attributed to its highly uniform core-shell morphology and exposure of much more active sites. Moreover, our as-prepared core-shell electrocatalysts will enable further investigation in other catalytic reactions.
ISSN:0360-2559
1525-6111
DOI:10.1080/03602559.2017.1354250