Paper-like 3-dimensional carbon nanotubes (CNTs)-microfiber hybrid: A promising macroscopic structure of CNTs

Fangting Jiang; Yuzhu Fang; Ye Liu; Li Chen; Qingsong Xue; Yong Lu; Jiaxing Lu; Ming Yuan He

doi:10.1039/b819083f

Paper-like 3-dimensional carbon nanotubes (CNTs)-microfiber hybrid: A promising macroscopic structure of CNTs

Fangting Jiang
, Yuzhu Fang
, Ye Liu
, Li Chen
, Qingsong Xue
, Yong Lu^*
, Jiaxing Lu
, Ming Yuan He

^*Corresponding author for this work

School of Chemistry and Molecular Engineering

East China Normal University

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

A promising macroscopic carbon nanotube (CNT) system has been developed by catalytic chemical vapor deposition method through CNT growth on a three-dimensional network of sinter-locked conductive metal microfibers (e.g., 8-μm-nickel fibers). This approach permits the desirable large-area fabrication and a unique combination of binderlessness, excellent thermal/electrical conductivity, macro-/meso-sized hierarchical porous structure and the individual/uniform dispersion of CNTs. CNTs with a yield of up to 50-60 wt% can be obtained until noticeable cracks or defects appear. This hybrid presents substantial potential in many applications, such as electrochemical energy storage. Owing to the excellent ion diffusivity, high conductivity and high concentration of active graphite edge planes, this hybrid delivers good capacitances (e.g., 47 F g^-1 CNTs) at high rates.

Original language	English
Pages (from-to)	3632-3637
Number of pages	6
Journal	Journal of Materials Chemistry
Volume	19
Issue number	22
DOIs	https://doi.org/10.1039/b819083f
State	Published - 2009

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title = "Paper-like 3-dimensional carbon nanotubes (CNTs)-microfiber hybrid: A promising macroscopic structure of CNTs",

abstract = "A promising macroscopic carbon nanotube (CNT) system has been developed by catalytic chemical vapor deposition method through CNT growth on a three-dimensional network of sinter-locked conductive metal microfibers (e.g., 8-μm-nickel fibers). This approach permits the desirable large-area fabrication and a unique combination of binderlessness, excellent thermal/electrical conductivity, macro-/meso-sized hierarchical porous structure and the individual/uniform dispersion of CNTs. CNTs with a yield of up to 50-60 wt\% can be obtained until noticeable cracks or defects appear. This hybrid presents substantial potential in many applications, such as electrochemical energy storage. Owing to the excellent ion diffusivity, high conductivity and high concentration of active graphite edge planes, this hybrid delivers good capacitances (e.g., 47 F g-1 CNTs) at high rates.",

author = "Fangting Jiang and Yuzhu Fang and Ye Liu and Li Chen and Qingsong Xue and Yong Lu and Jiaxing Lu and He, \{Ming Yuan\}",

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T2 - A promising macroscopic structure of CNTs

AU - Jiang, Fangting

AU - Fang, Yuzhu

AU - Liu, Ye

AU - Chen, Li

AU - Xue, Qingsong

AU - Lu, Yong

AU - Lu, Jiaxing

AU - He, Ming Yuan

PY - 2009

Y1 - 2009

N2 - A promising macroscopic carbon nanotube (CNT) system has been developed by catalytic chemical vapor deposition method through CNT growth on a three-dimensional network of sinter-locked conductive metal microfibers (e.g., 8-μm-nickel fibers). This approach permits the desirable large-area fabrication and a unique combination of binderlessness, excellent thermal/electrical conductivity, macro-/meso-sized hierarchical porous structure and the individual/uniform dispersion of CNTs. CNTs with a yield of up to 50-60 wt% can be obtained until noticeable cracks or defects appear. This hybrid presents substantial potential in many applications, such as electrochemical energy storage. Owing to the excellent ion diffusivity, high conductivity and high concentration of active graphite edge planes, this hybrid delivers good capacitances (e.g., 47 F g-1 CNTs) at high rates.

AB - A promising macroscopic carbon nanotube (CNT) system has been developed by catalytic chemical vapor deposition method through CNT growth on a three-dimensional network of sinter-locked conductive metal microfibers (e.g., 8-μm-nickel fibers). This approach permits the desirable large-area fabrication and a unique combination of binderlessness, excellent thermal/electrical conductivity, macro-/meso-sized hierarchical porous structure and the individual/uniform dispersion of CNTs. CNTs with a yield of up to 50-60 wt% can be obtained until noticeable cracks or defects appear. This hybrid presents substantial potential in many applications, such as electrochemical energy storage. Owing to the excellent ion diffusivity, high conductivity and high concentration of active graphite edge planes, this hybrid delivers good capacitances (e.g., 47 F g-1 CNTs) at high rates.

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Paper-like 3-dimensional carbon nanotubes (CNTs)-microfiber hybrid: A promising macroscopic structure of CNTs

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