Shape-engineerable composite fibers and their supercapacitor application

Kang Min Kim; Jae Ah Lee; Hyeon Jun Sim; Kyung Ah Kim; Rouhollah Jalili; Geoffrey M. Spinks; Seon Jeong Kim

doi:10.1039/c5nr07147j

Shape-engineerable composite fibers and their supercapacitor application

Kang Min Kim, Jae Ah Lee, Hyeon Jun Sim, Kyung Ah Kim, Rouhollah Jalili, Geoffrey M. Spinks, Seon Jeong Kim

Department of Energy and Materials Engineering

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

10 Scopus citations

Abstract

Due to excellent electrical and mechanical properties of carbon nano materials, it is of great interest to fabricate flexible, high conductive, and shape engineered carbon based fibers. As part of these approaches, hollow, twist, ribbon, and other various shapes of carbon based fibers have been researched for various functionality and application. In this paper, we suggest simple and effective method to control the fiber shape. We fabricate the three different shapes of hollow, twisted, and ribbon shaped fibers from wet spun giant graphene oxide (GGO)/single walled-nanotubes (SWNTs)/poly(vinyl alcohol) (PVA) gels. Each shaped fibers exhibit different mechanical properties. The average specific strengthes of the hollow, twist, and ribbon fibers presented here are 126.5, 106.9, and 38.0 MPa while strain are 9.3, 13.5, and 5%, respectively. Especially, the ribbon fiber shows high electrical conductivity (524 ± 64 S cm^-1) and areal capacitance (2.38 mF cm^-2).

Original language	English
Pages (from-to)	1910-1914
Number of pages	5
Journal	Nanoscale
Volume	8
Issue number	4
DOIs	https://doi.org/10.1039/c5nr07147j
State	Published - 28 Jan 2016

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title = "Shape-engineerable composite fibers and their supercapacitor application",

abstract = "Due to excellent electrical and mechanical properties of carbon nano materials, it is of great interest to fabricate flexible, high conductive, and shape engineered carbon based fibers. As part of these approaches, hollow, twist, ribbon, and other various shapes of carbon based fibers have been researched for various functionality and application. In this paper, we suggest simple and effective method to control the fiber shape. We fabricate the three different shapes of hollow, twisted, and ribbon shaped fibers from wet spun giant graphene oxide (GGO)/single walled-nanotubes (SWNTs)/poly(vinyl alcohol) (PVA) gels. Each shaped fibers exhibit different mechanical properties. The average specific strengthes of the hollow, twist, and ribbon fibers presented here are 126.5, 106.9, and 38.0 MPa while strain are 9.3, 13.5, and 5%, respectively. Especially, the ribbon fiber shows high electrical conductivity (524 ± 64 S cm-1) and areal capacitance (2.38 mF cm-2).",

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AU - Kim, Kang Min

AU - Lee, Jae Ah

AU - Sim, Hyeon Jun

AU - Kim, Kyung Ah

AU - Jalili, Rouhollah

AU - Spinks, Geoffrey M.

AU - Kim, Seon Jeong

PY - 2016/1/28

Y1 - 2016/1/28

N2 - Due to excellent electrical and mechanical properties of carbon nano materials, it is of great interest to fabricate flexible, high conductive, and shape engineered carbon based fibers. As part of these approaches, hollow, twist, ribbon, and other various shapes of carbon based fibers have been researched for various functionality and application. In this paper, we suggest simple and effective method to control the fiber shape. We fabricate the three different shapes of hollow, twisted, and ribbon shaped fibers from wet spun giant graphene oxide (GGO)/single walled-nanotubes (SWNTs)/poly(vinyl alcohol) (PVA) gels. Each shaped fibers exhibit different mechanical properties. The average specific strengthes of the hollow, twist, and ribbon fibers presented here are 126.5, 106.9, and 38.0 MPa while strain are 9.3, 13.5, and 5%, respectively. Especially, the ribbon fiber shows high electrical conductivity (524 ± 64 S cm-1) and areal capacitance (2.38 mF cm-2).

AB - Due to excellent electrical and mechanical properties of carbon nano materials, it is of great interest to fabricate flexible, high conductive, and shape engineered carbon based fibers. As part of these approaches, hollow, twist, ribbon, and other various shapes of carbon based fibers have been researched for various functionality and application. In this paper, we suggest simple and effective method to control the fiber shape. We fabricate the three different shapes of hollow, twisted, and ribbon shaped fibers from wet spun giant graphene oxide (GGO)/single walled-nanotubes (SWNTs)/poly(vinyl alcohol) (PVA) gels. Each shaped fibers exhibit different mechanical properties. The average specific strengthes of the hollow, twist, and ribbon fibers presented here are 126.5, 106.9, and 38.0 MPa while strain are 9.3, 13.5, and 5%, respectively. Especially, the ribbon fiber shows high electrical conductivity (524 ± 64 S cm-1) and areal capacitance (2.38 mF cm-2).

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Shape-engineerable composite fibers and their supercapacitor application

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