Synergistic effect of hierarchical nanopores in Co-doped cobalt oxide 3D flowers for electrochemical energy storage

Hybridizing hierarchical porous transition oxides composed of nanoscale building blocks is highly desirable for improving the electrochemical performance of energy storage. Herein, we contribute a fabrication of novel hierarchically nanoporous flower-shaped metal/transition oxide (Co/Co 3 O 4 -CoO)...

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Bibliographic Details
Published in:RSC advances 2020-12, Vol.1 (71), p.43825-43833
Main Authors: Deng, Xia, Zhang, Hong, Zhang, Junwei, Lei, Dongsheng, Peng, Yong
Format: Article
Language:English
Subjects:
Capacitance
Chemistry
Cobalt oxides
Diffusion rate
Electrochemical analysis
Energy storage
Flowers
Ion diffusion
Nanoparticles
Pore size
Pore size distribution
Porosity
Synergistic effect
Three dimensional flow
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Summary:Hybridizing hierarchical porous transition oxides composed of nanoscale building blocks is highly desirable for improving the electrochemical performance of energy storage. Herein, we contribute a fabrication of novel hierarchically nanoporous flower-shaped metal/transition oxide (Co/Co 3 O 4 -CoO) with controllable three-dimensional structure. The designed Co/Co 3 O 4 -CoO 3D flowers (3DFs) are made of petal-shaped nanoporous Co 3 O 4 -CoO nanosheets with tunable pore sizes, in which metallic Co nanoparticles tend to attach to the edge of larger ones. The hierarchically nanoporous 3DFs with bimodal pore size distribution and higher fraction of small nanopores exhibit a higher specific capacitance (902.3 F g −1 at current density of 2 A g −1 ) and better cyclability than the uniformly nanoporous 3DFs with unimodal pore size distribution and larger BET surface area. The enhanced capacitance is mainly derived from the synergistic effect of hierarchical nanopores, in which large nanopores disproportionately facilitate osmotic solution flux and diffusive solute transport, whilst small nanopores supply faster channels for electron transportation and ion diffusion. Our work should provide a strategy to fabricate a smart functional hierarchical nanoporous architecture with 3DF structures for the development of electrochemical energy storage materials. Hybridizing hierarchical porous transition oxides composed of nanoscale building blocks is highly desirable for improving the electrochemical performance of energy storage.
ISSN:2046-2069
2046-2069
DOI:10.1039/d0ra08319d