Oxide based supercapacitors: I-manganese oxides

Ling Bing Kong; Wenxiu Que; Lang Liu; Freddy Yin Chiang Boey; Zhichuan J. Xu; Kun Zhou; Sean Li; Tianshu Zhang; Chuanhu Wang

doi:10.1201/9781315153025

Oxide based supercapacitors: I-manganese oxides

Ling Bing Kong^*, Wenxiu Que, Lang Liu, Freddy Yin Chiang Boey, Zhichuan J. Xu, Kun Zhou, Sean Li, Tianshu Zhang, Chuanhu Wang

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Chapter

2 Citations (Scopus)

Abstract

Manganese oxide is among those that have pseudocapacitive (Faradic) behavior in aqueous solutions, while charge storage mechanism of manganese oxide electrodes has been well established [1, 2]. Pseudocapacitive reactions have been observed both on the surface and in bulk of the electrodes. Surface Faradaic reaction is due to the surface adsorption of electrolyte cations (C+ = H+, Li+, Na+ and K+) onto surface of the manganese oxide, given by [3, 4]: (Formula Presented) Bulk Faradaic reaction is related to intercalation or deintercalation of the electrolyte cations inside the manganese oxide, expressed as [3, 4]: (Formula Presented) Both charge storage mechanisms involve the redox reaction between III and IV oxidation states of Mn. As compared with the RuO2, hydrated manganese oxides have lower specific capacitances, usually in the range of 100-200 F.g-1 in alkali salt solutions. Moreover, the currently available MnO2-based supercapacitors have encountered serious limitations, such as intrinsic problem of MnO2, low specific capacitance, low energy density, structural instability, weak long-term cyclability, and low rate-capacity. For practical applications, the electrode materials should have high reversible capacitance, structural flexibility, long-time stability, fast cation diffusion at high charge-discharge rates, cost-effectiveness and environmental friendliness [5].

Original language	English
Title of host publication	Nanomaterials for Supercapacitors
Publisher	CRC Press
Pages	162-276
Number of pages	115
ISBN (Electronic)	9781498758437
ISBN (Print)	9781498758420
DOIs	https://doi.org/10.1201/9781315153025
Publication status	Published - Jan 1 2017
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2018 by Taylor & Francis Group, LLC.

ASJC Scopus Subject Areas

General Engineering
General Chemical Engineering
General Materials Science

Keywords

(Mn+Co)O•nHO
Chemical coprecipitation
Chemical precipitation
Cyclibility
Cyclic voltammetry
Cyclic voltammograms (CV)
Electrochemical impedance spectroscopy (EIS)
Galvanostatic charge
Hydrothermal reaction
Manganese oxide
Mn-Co mixed oxides
Mn-Fe mixed oxides
Mn-Ni mixed oxides
MnO
MnO
MnFeO
MnO
MnO-C
MnO-carbon nanotubes
MnO-CNTs
MnO-MWCNTs
MnO-nanocarbon
MnO-poly(o-phenylenediamine)
MnO-polyaniline
MnO-polypyrrole
MnO-polythiophene
MnO
MnO-RuO
Nanoflakes
Nanoflower
Nanoflowers
Nanoneedle
Nanorod
Nanorods
Nanosheet
Nanowhisker
Nanowhiskers
Pseudocapacitive reaction
Pseudocapacitor
RuMnO
Sol-gel
Solvo reaction
Supercapacitor
Voltammetric charge
α-MnO
γ-MnO
λ-MnO

Access to Document

10.1201/9781315153025

Cite this

@inbook{adb9c3c988484616868211f946e5a0c9,

title = "Oxide based supercapacitors: I-manganese oxides",

abstract = "Manganese oxide is among those that have pseudocapacitive (Faradic) behavior in aqueous solutions, while charge storage mechanism of manganese oxide electrodes has been well established [1, 2]. Pseudocapacitive reactions have been observed both on the surface and in bulk of the electrodes. Surface Faradaic reaction is due to the surface adsorption of electrolyte cations (C+ = H+, Li+, Na+ and K+) onto surface of the manganese oxide, given by [3, 4]: (Formula Presented) Bulk Faradaic reaction is related to intercalation or deintercalation of the electrolyte cations inside the manganese oxide, expressed as [3, 4]: (Formula Presented) Both charge storage mechanisms involve the redox reaction between III and IV oxidation states of Mn. As compared with the RuO2, hydrated manganese oxides have lower specific capacitances, usually in the range of 100-200 F.g-1 in alkali salt solutions. Moreover, the currently available MnO2-based supercapacitors have encountered serious limitations, such as intrinsic problem of MnO2, low specific capacitance, low energy density, structural instability, weak long-term cyclability, and low rate-capacity. For practical applications, the electrode materials should have high reversible capacitance, structural flexibility, long-time stability, fast cation diffusion at high charge-discharge rates, cost-effectiveness and environmental friendliness [5].",

keywords = "(Mn+Co)O•nHO, Chemical coprecipitation, Chemical precipitation, Cyclibility, Cyclic voltammetry, Cyclic voltammograms (CV), Electrochemical impedance spectroscopy (EIS), Galvanostatic charge, Hydrothermal reaction, Manganese oxide, Mn-Co mixed oxides, Mn-Fe mixed oxides, Mn-Ni mixed oxides, MnO, MnO, MnFeO, MnO, MnO-C, MnO-carbon nanotubes, MnO-CNTs, MnO-MWCNTs, MnO-nanocarbon, MnO-poly(o-phenylenediamine), MnO-polyaniline, MnO-polypyrrole, MnO-polythiophene, MnO, MnO-RuO, Nanoflakes, Nanoflower, Nanoflowers, Nanoneedle, Nanorod, Nanorods, Nanosheet, Nanowhisker, Nanowhiskers, Pseudocapacitive reaction, Pseudocapacitor, RuMnO, Sol-gel, Solvo reaction, Supercapacitor, Voltammetric charge, α-MnO, γ-MnO, λ-MnO",

author = "Kong, \{Ling Bing\} and Wenxiu Que and Lang Liu and Boey, \{Freddy Yin Chiang\} and Xu, \{Zhichuan J.\} and Kun Zhou and Sean Li and Tianshu Zhang and Chuanhu Wang",

note = "Publisher Copyright: {\textcopyright} 2018 by Taylor \& Francis Group, LLC.",

year = "2017",

month = jan,

day = "1",

doi = "10.1201/9781315153025",

language = "English",

isbn = "9781498758420",

pages = "162--276",

booktitle = "Nanomaterials for Supercapacitors",

publisher = "CRC Press",

}

TY - CHAP

T1 - Oxide based supercapacitors

T2 - I-manganese oxides

AU - Kong, Ling Bing

AU - Que, Wenxiu

AU - Liu, Lang

AU - Boey, Freddy Yin Chiang

AU - Xu, Zhichuan J.

AU - Zhou, Kun

AU - Li, Sean

AU - Zhang, Tianshu

AU - Wang, Chuanhu

PY - 2017/1/1

Y1 - 2017/1/1

N2 - Manganese oxide is among those that have pseudocapacitive (Faradic) behavior in aqueous solutions, while charge storage mechanism of manganese oxide electrodes has been well established [1, 2]. Pseudocapacitive reactions have been observed both on the surface and in bulk of the electrodes. Surface Faradaic reaction is due to the surface adsorption of electrolyte cations (C+ = H+, Li+, Na+ and K+) onto surface of the manganese oxide, given by [3, 4]: (Formula Presented) Bulk Faradaic reaction is related to intercalation or deintercalation of the electrolyte cations inside the manganese oxide, expressed as [3, 4]: (Formula Presented) Both charge storage mechanisms involve the redox reaction between III and IV oxidation states of Mn. As compared with the RuO2, hydrated manganese oxides have lower specific capacitances, usually in the range of 100-200 F.g-1 in alkali salt solutions. Moreover, the currently available MnO2-based supercapacitors have encountered serious limitations, such as intrinsic problem of MnO2, low specific capacitance, low energy density, structural instability, weak long-term cyclability, and low rate-capacity. For practical applications, the electrode materials should have high reversible capacitance, structural flexibility, long-time stability, fast cation diffusion at high charge-discharge rates, cost-effectiveness and environmental friendliness [5].

AB - Manganese oxide is among those that have pseudocapacitive (Faradic) behavior in aqueous solutions, while charge storage mechanism of manganese oxide electrodes has been well established [1, 2]. Pseudocapacitive reactions have been observed both on the surface and in bulk of the electrodes. Surface Faradaic reaction is due to the surface adsorption of electrolyte cations (C+ = H+, Li+, Na+ and K+) onto surface of the manganese oxide, given by [3, 4]: (Formula Presented) Bulk Faradaic reaction is related to intercalation or deintercalation of the electrolyte cations inside the manganese oxide, expressed as [3, 4]: (Formula Presented) Both charge storage mechanisms involve the redox reaction between III and IV oxidation states of Mn. As compared with the RuO2, hydrated manganese oxides have lower specific capacitances, usually in the range of 100-200 F.g-1 in alkali salt solutions. Moreover, the currently available MnO2-based supercapacitors have encountered serious limitations, such as intrinsic problem of MnO2, low specific capacitance, low energy density, structural instability, weak long-term cyclability, and low rate-capacity. For practical applications, the electrode materials should have high reversible capacitance, structural flexibility, long-time stability, fast cation diffusion at high charge-discharge rates, cost-effectiveness and environmental friendliness [5].

KW - (Mn+Co)O•nHO

KW - Chemical coprecipitation

KW - Chemical precipitation

KW - Cyclibility

KW - Cyclic voltammetry

KW - Cyclic voltammograms (CV)

KW - Electrochemical impedance spectroscopy (EIS)

KW - Galvanostatic charge

KW - Hydrothermal reaction

KW - Manganese oxide

KW - Mn-Co mixed oxides

KW - Mn-Fe mixed oxides

KW - Mn-Ni mixed oxides

KW - MnO

KW - MnFeO

KW - MnO

KW - MnO-C

KW - MnO-carbon nanotubes

KW - MnO-CNTs

KW - MnO-MWCNTs

KW - MnO-nanocarbon

KW - MnO-poly(o-phenylenediamine)

KW - MnO-polyaniline

KW - MnO-polypyrrole

KW - MnO-polythiophene

KW - MnO

KW - MnO-RuO

KW - Nanoflakes

KW - Nanoflower

KW - Nanoflowers

KW - Nanoneedle

KW - Nanorod

KW - Nanorods

KW - Nanosheet

KW - Nanowhisker

KW - Nanowhiskers

KW - Pseudocapacitive reaction

KW - Pseudocapacitor

KW - RuMnO

KW - Sol-gel

KW - Solvo reaction

KW - Supercapacitor

KW - Voltammetric charge

KW - α-MnO

KW - γ-MnO

KW - λ-MnO

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UR - http://www.scopus.com/inward/citedby.url?scp=85053523410&partnerID=8YFLogxK

U2 - 10.1201/9781315153025

DO - 10.1201/9781315153025

M3 - Chapter

AN - SCOPUS:85053523410

SN - 9781498758420

SP - 162

EP - 276

BT - Nanomaterials for Supercapacitors

PB - CRC Press

ER -

Oxide based supercapacitors: I-manganese oxides

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

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