A new high-performance cathode material for rechargeable lithium-ion batteries: Polypyrrole/vanadium oxide nanotubes

Cui, Chaojun; Wu, Guangming; Yang, Haiyan; She, Shi-Feng; Shen, Jun; Zhou, Bin; Zhang, Zhihua

doi:10.1016/j.electacta.2010.07.087

Cited by 46 publications

(22 citation statements)

References 25 publications

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“…126 Not surprisingly therefore PPy has already been applied in a wide variety of areas such as rechargeable lithium batteries, 16,127 low temperature fuel cell technology,128 medical applications, 129,130 and volatile organic compound detection. 131,132 It has also been investigated as a material for "artificial muscles" that would offer numerous advantages over traditional motor actuation.…”

Section: Polyaniline Fibresmentioning

confidence: 99%

Developments in conducting polymer fibres: from established spinning methods toward advanced applications

2016

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Conducting polymers have received increasing attention in both fundamental research and various fields of application in recent decades, ranging in use from biomaterials to renewable energy storage devices. Processing of conducting polymers into fibrillar structures through spinning has provided some unique capabilities to their final applications. Compared with non fibrillar forms, conducting polymer fibres are expected to display improved properties arising mainly from their low dimensions, well-oriented polymer chains, light weight and large surface area to volume ratio. Spinning methods have been employed effectively to produce technological conducting fibres from nanoscale to hundreds of micrometre sizes with controlled properties. This review considers the history, categories, the latest research and development, pristine and composite conducting polymer fibres and current/future applications of them while focus on spinning methods related to conducting polymer fibres. Inherently conducting polymers have received increasing attention in both fundamental research and various fields of application in recent decades, ranging in use from biomaterials to renewable energy storage devices. Processing of conducting polymers into fibrillar structures through spinning has provided some unique capabilities to their final applications. Compared with non fibrillar forms, conducting polymer fibres are expected to display improved properties arising mainly from their low dimensions, well-oriented polymer chains, light weight and large surface area to volume ratio. Spinning methods have been employed effectively to produce technological conducting fibres from nanoscale to hundreds of micrometre sizes with controlled properties. This review considers the history, categories, the latest research and development, pristine and composite conducting polymer fibres and current/future of applications of them while focus on spinning methods related to conducting polymer fibres. Disciplines Engineering | Physical Sciences and Mathematics

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Section: Polyaniline Fibresmentioning

confidence: 99%

Developments in conducting polymer fibres: from established spinning methods toward advanced applications

2016

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“…In addition, the intercalation of PEO in MoO 3 nanobelts, significantly enhances the cycling stability and reversibility of insertion/extraction of Li + ions. It is effectively shielding the electrostatic interaction between Li + ions and MoO 3 layers [53,60]. These results revealed that PEO surfactant MoO 3 nanobelts are encouraging positive electrode materials for lithium ion batteries.…”

Section: Evaluation Of Battery Discharge Profilesmentioning

confidence: 84%

Synthesis and characterization of α-MoO3 nanobelt composite positive electrode materials for lithium battery application

Nadimicherla

Chen

Guo

2015

Materials Research Bulletin

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“…When fabricated as an ARLIB full cell with the PANI/Fe 2 O 3 multichanneled nanotube anode and a LiMn 2 O 4 cathode, an initial discharge capacity of 50.5 mAh g -1 is obtained at the current rate of 150 mA g -1 , with superior capacity retention of 73.3% after over 1000 charge/discharge cycles (Fig 9 c- Template utilized in synthesis of core shell CuO/PPy composites led to improved stability, electric conductivity and electrochemical performance 222 .Surface adsorption of PDDA on LiMn 2 O 4 particles extends the lifetime of the LIB by arresting the Mn + dissolution, thus increasing battery stability 223 . The improved electrochemical performance of NiO/PPy composite was also studied 224 .Cation exchange technique was used for high performance cathode material (PPy/VOx-NTs) 225 . Dissolution of metal oxide on LiNi 1/3 Mn 1/3 Co 1/3 O 2 / Li x V 2 O 5 /PANi composite was studied 226 .…”

Section: Miscellaneous Methodsmentioning

confidence: 99%

Conducting polymers and their inorganic composites for advanced Li-ion batteries: a review

2015

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A new high-performance cathode material for rechargeable lithium-ion batteries: Polypyrrole/vanadium oxide nanotubes

Cited by 46 publications

References 25 publications

Developments in conducting polymer fibres: from established spinning methods toward advanced applications

Developments in conducting polymer fibres: from established spinning methods toward advanced applications

Synthesis and characterization of α-MoO3 nanobelt composite positive electrode materials for lithium battery application

Conducting polymers and their inorganic composites for advanced Li-ion batteries: a review

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