Rechargeable organic batteries using chloro-substituted naphthazarin derivatives as positive electrode materials

The use of redox active organic compounds as an alternative positive electrode material of rechargeable lithium batteries can be a solution for the resource issues of the current battery system. To satisfy both the high capacity and long cycle life of the batteries using organic active materials, na...

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Veröffentlicht in:	Journal of materials science 2017-10, Vol.52 (20), p.12401-12408
Hauptverfasser:	Yao, Masaru, Umetani, Shinji, Ando, Hisanori, Kiyobayashi, Tetsu, Takeichi, Nobuhiko, Kondo, Ryota, Takeshita, Hiroyuki T.
Format:	Artikel
Sprache:	eng
Schlagworte:	Batteries Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Crystallography and Scattering Methods Derivatives Electrochromism Electrode materials Electrodes Electron transfer Electron transport Energy Materials Lithium Lithium batteries Materials Science Materials substitution Organic compounds Polymer Sciences Rechargeable batteries Solid Mechanics Stability
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container_issue	20
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container_title	Journal of materials science
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creator	Yao, Masaru Umetani, Shinji Ando, Hisanori Kiyobayashi, Tetsu Takeichi, Nobuhiko Kondo, Ryota Takeshita, Hiroyuki T.
description	The use of redox active organic compounds as an alternative positive electrode material of rechargeable lithium batteries can be a solution for the resource issues of the current battery system. To satisfy both the high capacity and long cycle life of the batteries using organic active materials, naphthazarin (5,8-dihydroxy-1,4-naphthoquinone) derivatives, which potentially exhibit a four-electron transfer redox reaction, were investigated. While the unsubstituted naphthazarin lithium salt ( 1 ), having a high theoretical capacity of up to about 550 mAh g −1 , showed only half the expected capacity and a short cycle life as a positive electrode active material, the chloro-substituted ones ( 1 - Cl 2 , 1 - Cl 4 ) exhibited improved properties in both their initial capacity utilization and cycle life. In addition, the high stability of a chloro-substituted naphthazarin salt ( 1 - Cl 4 ) was supported by a reversible electrochromic behavior during the redox reaction. The substituent effect of the naphthazarin derivatives on the cycle stability was discussed with respect to the battery performance and electrochromic behavior. Also, a guide for designing a new organic active material which shows a high capacity and long cycle life is suggested.
doi_str_mv	10.1007/s10853-017-1368-z
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To satisfy both the high capacity and long cycle life of the batteries using organic active materials, naphthazarin (5,8-dihydroxy-1,4-naphthoquinone) derivatives, which potentially exhibit a four-electron transfer redox reaction, were investigated. While the unsubstituted naphthazarin lithium salt ( 1 ), having a high theoretical capacity of up to about 550 mAh g −1 , showed only half the expected capacity and a short cycle life as a positive electrode active material, the chloro-substituted ones ( 1 - Cl 2 , 1 - Cl 4 ) exhibited improved properties in both their initial capacity utilization and cycle life. In addition, the high stability of a chloro-substituted naphthazarin salt ( 1 - Cl 4 ) was supported by a reversible electrochromic behavior during the redox reaction. The substituent effect of the naphthazarin derivatives on the cycle stability was discussed with respect to the battery performance and electrochromic behavior. 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To satisfy both the high capacity and long cycle life of the batteries using organic active materials, naphthazarin (5,8-dihydroxy-1,4-naphthoquinone) derivatives, which potentially exhibit a four-electron transfer redox reaction, were investigated. While the unsubstituted naphthazarin lithium salt ( 1 ), having a high theoretical capacity of up to about 550 mAh g −1 , showed only half the expected capacity and a short cycle life as a positive electrode active material, the chloro-substituted ones ( 1 - Cl 2 , 1 - Cl 4 ) exhibited improved properties in both their initial capacity utilization and cycle life. In addition, the high stability of a chloro-substituted naphthazarin salt ( 1 - Cl 4 ) was supported by a reversible electrochromic behavior during the redox reaction. The substituent effect of the naphthazarin derivatives on the cycle stability was discussed with respect to the battery performance and electrochromic behavior. 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To satisfy both the high capacity and long cycle life of the batteries using organic active materials, naphthazarin (5,8-dihydroxy-1,4-naphthoquinone) derivatives, which potentially exhibit a four-electron transfer redox reaction, were investigated. While the unsubstituted naphthazarin lithium salt ( 1 ), having a high theoretical capacity of up to about 550 mAh g −1 , showed only half the expected capacity and a short cycle life as a positive electrode active material, the chloro-substituted ones ( 1 - Cl 2 , 1 - Cl 4 ) exhibited improved properties in both their initial capacity utilization and cycle life. In addition, the high stability of a chloro-substituted naphthazarin salt ( 1 - Cl 4 ) was supported by a reversible electrochromic behavior during the redox reaction. The substituent effect of the naphthazarin derivatives on the cycle stability was discussed with respect to the battery performance and electrochromic behavior. 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subjects	Batteries Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Crystallography and Scattering Methods Derivatives Electrochromism Electrode materials Electrodes Electron transfer Electron transport Energy Materials Lithium Lithium batteries Materials Science Materials substitution Organic compounds Polymer Sciences Rechargeable batteries Solid Mechanics Stability
title	Rechargeable organic batteries using chloro-substituted naphthazarin derivatives as positive electrode materials
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