High-performance organic electrolyte supercapacitors based on intrinsically powdery carbon aerogels

Xidong Lin; He Lou; Wenrui Lu; Fei Xu; Ruowen Fu; Dingcai Wu

doi:10.1016/j.cclet.2017.11.024

High-performance organic electrolyte supercapacitors based on intrinsically powdery carbon aerogels

Xidong Lin
, He Lou
, Wenrui Lu
, Fei Xu
, Ruowen Fu
, Dingcai Wu

School of Materials Sience and Engineering

Sun Yat-Sen University

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

37 Scopus citations

Abstract

A novel class of powdery carbon aerogels (PCAs) has been developed by the union of microemulsion polymerization and hypercrosslinking, followed by carbonization. The resulting aerogels are in a microscale powdery form, demonstrate a well-defined 3D interconnected nanonetwork with hierarchical pores derived from numerous interstitial nanopores and intraparticle micropores, and exhibit high surface area (up to 1969 m²/g). Benefiting from these structural features, PCAs show impressive capacitive performances when utilized as electrodes for organic electrolyte supercapacitors, including large capacitances of up to 152 F/g, high energy densities of 37-15 Wh/kg at power densities of 34–6750 W/kg, and robust cycling stability.

Original language	English
Pages (from-to)	633-636
Number of pages	4
Journal	Chinese Chemical Letters
Volume	29
Issue number	4
DOIs	https://doi.org/10.1016/j.cclet.2017.11.024
State	Published - Apr 2018

Keywords

Hierarchical pore
High surface area
Organic electrolyte
Powdery carbon aerogel
Supercapacitor

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10.1016/j.cclet.2017.11.024

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title = "High-performance organic electrolyte supercapacitors based on intrinsically powdery carbon aerogels",

abstract = "A novel class of powdery carbon aerogels (PCAs) has been developed by the union of microemulsion polymerization and hypercrosslinking, followed by carbonization. The resulting aerogels are in a microscale powdery form, demonstrate a well-defined 3D interconnected nanonetwork with hierarchical pores derived from numerous interstitial nanopores and intraparticle micropores, and exhibit high surface area (up to 1969 m2/g). Benefiting from these structural features, PCAs show impressive capacitive performances when utilized as electrodes for organic electrolyte supercapacitors, including large capacitances of up to 152 F/g, high energy densities of 37-15 Wh/kg at power densities of 34–6750 W/kg, and robust cycling stability.",

keywords = "Hierarchical pore, High surface area, Organic electrolyte, Powdery carbon aerogel, Supercapacitor",

author = "Xidong Lin and He Lou and Wenrui Lu and Fei Xu and Ruowen Fu and Dingcai Wu",

note = "Publisher Copyright: {\textcopyright} 2017",

year = "2018",

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doi = "10.1016/j.cclet.2017.11.024",

language = "英语",

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TY - JOUR

T1 - High-performance organic electrolyte supercapacitors based on intrinsically powdery carbon aerogels

AU - Lin, Xidong

AU - Lou, He

AU - Lu, Wenrui

AU - Xu, Fei

AU - Fu, Ruowen

AU - Wu, Dingcai

PY - 2018/4

Y1 - 2018/4

N2 - A novel class of powdery carbon aerogels (PCAs) has been developed by the union of microemulsion polymerization and hypercrosslinking, followed by carbonization. The resulting aerogels are in a microscale powdery form, demonstrate a well-defined 3D interconnected nanonetwork with hierarchical pores derived from numerous interstitial nanopores and intraparticle micropores, and exhibit high surface area (up to 1969 m2/g). Benefiting from these structural features, PCAs show impressive capacitive performances when utilized as electrodes for organic electrolyte supercapacitors, including large capacitances of up to 152 F/g, high energy densities of 37-15 Wh/kg at power densities of 34–6750 W/kg, and robust cycling stability.

AB - A novel class of powdery carbon aerogels (PCAs) has been developed by the union of microemulsion polymerization and hypercrosslinking, followed by carbonization. The resulting aerogels are in a microscale powdery form, demonstrate a well-defined 3D interconnected nanonetwork with hierarchical pores derived from numerous interstitial nanopores and intraparticle micropores, and exhibit high surface area (up to 1969 m2/g). Benefiting from these structural features, PCAs show impressive capacitive performances when utilized as electrodes for organic electrolyte supercapacitors, including large capacitances of up to 152 F/g, high energy densities of 37-15 Wh/kg at power densities of 34–6750 W/kg, and robust cycling stability.

KW - Hierarchical pore

KW - High surface area

KW - Organic electrolyte

KW - Powdery carbon aerogel

KW - Supercapacitor

UR - https://www.scopus.com/pages/publications/85036570799

U2 - 10.1016/j.cclet.2017.11.024

DO - 10.1016/j.cclet.2017.11.024

M3 - 文章

AN - SCOPUS:85036570799

SN - 1001-8417

VL - 29

SP - 633

EP - 636

JO - Chinese Chemical Letters

JF - Chinese Chemical Letters

IS - 4

ER -

High-performance organic electrolyte supercapacitors based on intrinsically powdery carbon aerogels

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Keywords

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