Single-walled carbon-nanotube networks on large-area glass substrate by the dip-coating method

Eui Yun Jang; Tae June Kang; Hyeong Wook Im; Dae Weon Kim; Yong Hyup Kim

doi:10.1002/smll.200800600

Single-walled carbon-nanotube networks on large-area glass substrate by the dip-coating method

Eui Yun Jang, Tae June Kang, Hyeong Wook Im, Dae Weon Kim, Yong Hyup Kim

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

82 Scopus citations

Abstract

Highly uniform and large-area single-walled carbon-nanotube (SWNT) networks are realized by the dip-coating method, which is based on fundamental fluid-dynamic phenomena such as capillary condensation and surface tension. The changes in the polarity and hydration properties of the substrate affect the morphology of the SWNT networks and result in nonlinear growth of the networks in the repetitive dip-coating process. The density and the thickness of the SWNT networks are controlled by processing variables including number of dip coatings, concentration of SWNT colloidal solution, and withdrawal velocity. The networks have uniform sheet resistances and high optical transmittance in the visible wavelength range.

Original language	English
Pages (from-to)	2255-2261
Number of pages	7
Journal	Small
Volume	4
Issue number	12
DOIs	https://doi.org/10.1002/smll.200800600
State	Published - Dec 2008
Externally published	Yes

Keywords

Carbon-nanotube networks
Dip coating
Self-assembly
Single-walled carbon nanotubes

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10.1002/smll.200800600

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title = "Single-walled carbon-nanotube networks on large-area glass substrate by the dip-coating method",

abstract = "Highly uniform and large-area single-walled carbon-nanotube (SWNT) networks are realized by the dip-coating method, which is based on fundamental fluid-dynamic phenomena such as capillary condensation and surface tension. The changes in the polarity and hydration properties of the substrate affect the morphology of the SWNT networks and result in nonlinear growth of the networks in the repetitive dip-coating process. The density and the thickness of the SWNT networks are controlled by processing variables including number of dip coatings, concentration of SWNT colloidal solution, and withdrawal velocity. The networks have uniform sheet resistances and high optical transmittance in the visible wavelength range.",

keywords = "Carbon-nanotube networks, Dip coating, Self-assembly, Single-walled carbon nanotubes",

author = "Jang, {Eui Yun} and Kang, {Tae June} and Im, {Hyeong Wook} and Kim, {Dae Weon} and Kim, {Yong Hyup}",

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doi = "10.1002/smll.200800600",

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AU - Jang, Eui Yun

AU - Kang, Tae June

AU - Im, Hyeong Wook

AU - Kim, Dae Weon

AU - Kim, Yong Hyup

PY - 2008/12

Y1 - 2008/12

N2 - Highly uniform and large-area single-walled carbon-nanotube (SWNT) networks are realized by the dip-coating method, which is based on fundamental fluid-dynamic phenomena such as capillary condensation and surface tension. The changes in the polarity and hydration properties of the substrate affect the morphology of the SWNT networks and result in nonlinear growth of the networks in the repetitive dip-coating process. The density and the thickness of the SWNT networks are controlled by processing variables including number of dip coatings, concentration of SWNT colloidal solution, and withdrawal velocity. The networks have uniform sheet resistances and high optical transmittance in the visible wavelength range.

AB - Highly uniform and large-area single-walled carbon-nanotube (SWNT) networks are realized by the dip-coating method, which is based on fundamental fluid-dynamic phenomena such as capillary condensation and surface tension. The changes in the polarity and hydration properties of the substrate affect the morphology of the SWNT networks and result in nonlinear growth of the networks in the repetitive dip-coating process. The density and the thickness of the SWNT networks are controlled by processing variables including number of dip coatings, concentration of SWNT colloidal solution, and withdrawal velocity. The networks have uniform sheet resistances and high optical transmittance in the visible wavelength range.

KW - Carbon-nanotube networks

KW - Dip coating

KW - Self-assembly

KW - Single-walled carbon nanotubes

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ER -

Single-walled carbon-nanotube networks on large-area glass substrate by the dip-coating method

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Keywords

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