Interface-Confined High Crystalline Growth of Semiconducting Polymers at Graphene Fibers for High-Performance Wearable Supercapacitors

Suchithra Padmajan Sasikala; Kyung Eun Lee; Joonwon Lim; Ho Jin Lee; Sung Hwan Koo; In Ho Kim; Hong Ju Jung; Sang Ouk Kim

doi:10.1021/acsnano.7b05029

Interface-Confined High Crystalline Growth of Semiconducting Polymers at Graphene Fibers for High-Performance Wearable Supercapacitors

Suchithra Padmajan Sasikala, Kyung Eun Lee, Joonwon Lim, Ho Jin Lee, Sung Hwan Koo, In Ho Kim, Hong Ju Jung, Sang Ouk Kim

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

109 Citations (Scopus)

Abstract

We report graphene@polymer core-shell fibers (G@PFs) composed of N and Cu codoped porous graphene fiber cores uniformly coated with semiconducting polymer shell layers with superb electrochemical characteristics. Aqueous/organic interface-confined polymerization method produced robust highly crystalline uniform semiconducting polymer shells with high electrical conductivity and redox activity. When the resultant core-shell fibers are utilized for fiber supercapacitor application, high areal/volume capacitance and energy densities are attained along with long-term cycle stability. Desirable combination of mechanical flexibility, electrochemical properties, and facile process scalability makes our G@PFs particularly promising for portable and wearable electronics.

Original language	English
Pages (from-to)	9424-9434
Number of pages	11
Journal	ACS Nano
Volume	11
Issue number	9
DOIs	https://doi.org/10.1021/acsnano.7b05029
Publication status	Published - 26 Sept 2017

Bibliographical note

Publisher Copyright:
© 2017 American Chemical Society.

Keywords

conducting polymer
fiber
graphene
interfacial polymerization
supercapacitor

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10.1021/acsnano.7b05029

Cite this

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title = "Interface-Confined High Crystalline Growth of Semiconducting Polymers at Graphene Fibers for High-Performance Wearable Supercapacitors",

abstract = "We report graphene@polymer core-shell fibers (G@PFs) composed of N and Cu codoped porous graphene fiber cores uniformly coated with semiconducting polymer shell layers with superb electrochemical characteristics. Aqueous/organic interface-confined polymerization method produced robust highly crystalline uniform semiconducting polymer shells with high electrical conductivity and redox activity. When the resultant core-shell fibers are utilized for fiber supercapacitor application, high areal/volume capacitance and energy densities are attained along with long-term cycle stability. Desirable combination of mechanical flexibility, electrochemical properties, and facile process scalability makes our G@PFs particularly promising for portable and wearable electronics.",

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AU - Padmajan Sasikala, Suchithra

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AU - Lim, Joonwon

AU - Lee, Ho Jin

AU - Koo, Sung Hwan

AU - Kim, In Ho

AU - Jung, Hong Ju

AU - Kim, Sang Ouk

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Y1 - 2017/9/26

N2 - We report graphene@polymer core-shell fibers (G@PFs) composed of N and Cu codoped porous graphene fiber cores uniformly coated with semiconducting polymer shell layers with superb electrochemical characteristics. Aqueous/organic interface-confined polymerization method produced robust highly crystalline uniform semiconducting polymer shells with high electrical conductivity and redox activity. When the resultant core-shell fibers are utilized for fiber supercapacitor application, high areal/volume capacitance and energy densities are attained along with long-term cycle stability. Desirable combination of mechanical flexibility, electrochemical properties, and facile process scalability makes our G@PFs particularly promising for portable and wearable electronics.

AB - We report graphene@polymer core-shell fibers (G@PFs) composed of N and Cu codoped porous graphene fiber cores uniformly coated with semiconducting polymer shell layers with superb electrochemical characteristics. Aqueous/organic interface-confined polymerization method produced robust highly crystalline uniform semiconducting polymer shells with high electrical conductivity and redox activity. When the resultant core-shell fibers are utilized for fiber supercapacitor application, high areal/volume capacitance and energy densities are attained along with long-term cycle stability. Desirable combination of mechanical flexibility, electrochemical properties, and facile process scalability makes our G@PFs particularly promising for portable and wearable electronics.

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KW - graphene

KW - interfacial polymerization

KW - supercapacitor

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Interface-Confined High Crystalline Growth of Semiconducting Polymers at Graphene Fibers for High-Performance Wearable Supercapacitors

Abstract

Bibliographical note

Keywords

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