Designed Synthesis and Supercapacitor Electrode of V2O3@C Core‐shell Structured Nanorods with Excellent Pseudo‐capacitance in Na2SO4 Neutral Electrolyte

Zhang, Yifu

doi:10.1002/slct.201702705

Cited by 12 publications

(2 citation statements)

References 53 publications

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“…Therefore, the electrochemical behaviors for polymeric electrode materials were directly evaluated without the influences of additional additives, as a result, relatively poor cycle performance could be observed. However, there is still a significant improvement in the cycling stability could be achieved compared to the previously reported PANi/PPy composite nanofibers and inorganic composites as presented in Table . In particular, when III–PANi nanofibers with a relatively small diameter and smooth surface were used as the seed for the formation of PPy, a compact PPy shell and strong synergistic interaction between PANi core and PPy shell could greatly enhance the structural stability of the composite nanofibers.…”

Section: Resultsmentioning

confidence: 85%

Scalable Flowing Polymerization and Enhanced Capacitive Properties for Core–Shell Structured Composite Nanofibers toward Highly Efficient Charge Storage in Neutral Electrolytes

Shen

Liang

Yan

et al. 2021

ACS Appl. Energy Mater.

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With the rapid development of portable and wearable devices, the first priority should be given to safety, and furthermore, more attention needs to be paid to polymeric supercapacitors operating in neutral aqueous electrolytes. As a kind of cost-efficient and high-performance electrode materials, core–shell polyaniline (PANi)/polypyrrole (PPy) composite nanofibers are constructed continuously through flowing polymerization in totally aqueous solution without any surfactants and special templates. Moreover, the influences of PANi nanofibers obtained in three different flowing configurations on the growth of the PPy shell and capacitive behaviors of the composite nanofibers are discussed. It is found that significant enhancement on charge storage ability of the composite nanofibers in neutral electrolyte could be achieved, benefiting from the formation of a more compact PPy shell and strong synergistic interaction between the PANi core and PPy shell. The maximal specific capacitance of 670.0 F g–1 was obtained at the current density of 1 A g–1 in Na2SO4 electrolyte, and the corresponding assembled device exhibited a large energy density of 14.8 Wh kg–1 at a power density of 343.1 W kg–1. Such rational structural design and scalable fabrication are expected to pave the way toward the development of conducting polymers as cost-efficient electrode materials in portable and wearable devices especially operating in neutral aqueous electrolytes.

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Section: Resultsmentioning

confidence: 85%

Scalable Flowing Polymerization and Enhanced Capacitive Properties for Core–Shell Structured Composite Nanofibers toward Highly Efficient Charge Storage in Neutral Electrolytes

Shen

Liang

Yan

et al. 2021

ACS Appl. Energy Mater.

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“…By far, many researches about metal oxides in morphology control have been exerted. Zhang et al synthesized V 2 O 3 @C nanorod with a thin carbon layer [94]. Seen from the electrochemical analysis, the capacitance retention of V 2 O 3 @C nanorods was 100% and 66% after 700 and 1000 cycles, respectively.…”

Section: Structure and Morphology Controlmentioning

confidence: 99%

Carbon coating on metal oxide materials for electrochemical energy storage

Liu

Shao

et al. 2021

Nanotechnology

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During the past decades, nano-structured metal oxide electrode materials have received growing attention due to their low development cost and high theoretical specific capacity, accordingly, quite a lot of metal oxide electrode materials are being used in electrochemical energy storage devices. However, the further development was limited by the relatively low electrical conductivity and the volume expansion during electrochemical reactions. Thus, many approaches have been proposed to obtain high-efficiency metal oxide electrode materials, such as designing nanomaterials with ideal morphology and high specific surface area, optimizing with carbon-based materials (such as graphene and glucose) to prepare nanocomposites, combining with conductive substrates to enhance the conductivity of electrodes, etc. Owning to the advantages of low cost and high chemical stability of carbon materials, core–shell structure formed by carbon-coated metal oxides is considered to be a promising solution to solve these problems. Therefore, this review mainly focuses on recent research advances in the field of carbon-coated metal oxides for energy storage, summarizing the advantages and disadvantages of common metal oxides and different types of carbon sources, and proposing methods to optimize the material properties in terms of structure and morphology, carbon layer thickness, coating method, specific surface area and pore size distribution, as well as improving electrical conductivity. In addition, the double or multi-layer coating strategy is also a reflection of the continuous development of carbon coating method. Hopefully, this rereview may provide a new direction for the renewal and development of future energy storage electrode materials.

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Insights on the electrochemical properties of lattice strain induced layered V2O3–Al2O3 nanocomposites derived from the carbonization process

Naveen

Durgalakshmi

Mohanraj

et al. 2023

J Mater Sci: Mater Electron

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Designed Synthesis and Supercapacitor Electrode of V₂O₃@C Core‐shell Structured Nanorods with Excellent Pseudo‐capacitance in Na₂SO₄ Neutral Electrolyte

Cited by 12 publications

References 53 publications

Scalable Flowing Polymerization and Enhanced Capacitive Properties for Core–Shell Structured Composite Nanofibers toward Highly Efficient Charge Storage in Neutral Electrolytes

Scalable Flowing Polymerization and Enhanced Capacitive Properties for Core–Shell Structured Composite Nanofibers toward Highly Efficient Charge Storage in Neutral Electrolytes

Carbon coating on metal oxide materials for electrochemical energy storage

Insights on the electrochemical properties of lattice strain induced layered V2O3–Al2O3 nanocomposites derived from the carbonization process

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