Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte

Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte

Hard carbon is widely studied as a promising negative electrode in sodium-ion batteries. To achieve its stable charge-discharge reaction, a fluorine-rich passivation film arising from a fluorinated salt or solvent in an electrolyte was demonstrated to be effective, but its essential role remained un...

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Main Authors: Yusuke MORIKAWA, Yuki YAMADA, Kyosuke DOI, Shin-ichi NISHIMURA, Atsuo YAMADA
Format: Article
Language:English
Published: The Electrochemical Society of Japan 2020-05-01
Series:Electrochemistry
Subjects:
sodium-ion batteries
hard carbon
electrolyte
fluorine
Online Access:https://www.jstage.jst.go.jp/article/electrochemistry/88/3/88_19-00073/_pdf/-char/en
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spelling doaj-029987bd4ba54f24943432420c0e9e782021-09-02T07:55:06ZengThe Electrochemical Society of JapanElectrochemistry2186-24512020-05-0188315115610.5796/electrochemistry.19-00073electrochemistryReversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt ElectrolyteYusuke MORIKAWA0Yuki YAMADA1Kyosuke DOI2Shin-ichi NISHIMURA3Atsuo YAMADA4Department of Chemical System Engineering, The University of TokyoDepartment of Chemical System Engineering, The University of TokyoDepartment of Chemical System Engineering, The University of TokyoDepartment of Chemical System Engineering, The University of TokyoDepartment of Chemical System Engineering, The University of TokyoHard carbon is widely studied as a promising negative electrode in sodium-ion batteries. To achieve its stable charge-discharge reaction, a fluorine-rich passivation film arising from a fluorinated salt or solvent in an electrolyte was demonstrated to be effective, but its essential role remained unclear. Here, we report a sodium tetraphenylborate (NaBPh4)/1,2-dimethoxyethane (DME) electrolyte that is free from fluorine but enables the highly stable and high-rate charge-discharge cycling of hard carbon electrodes as compared to other combinations of Na salts and solvents. Surface analysis of the cycled electrode shows that the NaBPh4 is not decomposed during the cycle and that solid electrolyte interphase (SEI) is derived from DME. Hence, fluorine-based components are not indispensable to stabilize the hard carbon/electrolyte interface. The DME-derived SEI, though containing no F component, can highly stabilize the interface to enable the reversible and high-rate cycling of hard carbon.https://www.jstage.jst.go.jp/article/electrochemistry/88/3/88_19-00073/_pdf/-char/ensodium-ion batterieshard carbonelectrolytefluorine
collection DOAJ
language English
format Article
sources DOAJ
author Yusuke MORIKAWA
Yuki YAMADA
Kyosuke DOI
Shin-ichi NISHIMURA
Atsuo YAMADA
spellingShingle Yusuke MORIKAWA
Yuki YAMADA
Kyosuke DOI
Shin-ichi NISHIMURA
Atsuo YAMADA
Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte
Electrochemistry
sodium-ion batteries
hard carbon
electrolyte
fluorine
author_facet Yusuke MORIKAWA
Yuki YAMADA
Kyosuke DOI
Shin-ichi NISHIMURA
Atsuo YAMADA
author_sort Yusuke MORIKAWA
title Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte
title_short Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte
title_full Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte
title_fullStr Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte
title_full_unstemmed Reversible and High-rate Hard Carbon Negative Electrodes in a Fluorine-free Sodium-salt Electrolyte
title_sort reversible and high-rate hard carbon negative electrodes in a fluorine-free sodium-salt electrolyte
publisher The Electrochemical Society of Japan
series Electrochemistry
issn 2186-2451
publishDate 2020-05-01
description Hard carbon is widely studied as a promising negative electrode in sodium-ion batteries. To achieve its stable charge-discharge reaction, a fluorine-rich passivation film arising from a fluorinated salt or solvent in an electrolyte was demonstrated to be effective, but its essential role remained unclear. Here, we report a sodium tetraphenylborate (NaBPh4)/1,2-dimethoxyethane (DME) electrolyte that is free from fluorine but enables the highly stable and high-rate charge-discharge cycling of hard carbon electrodes as compared to other combinations of Na salts and solvents. Surface analysis of the cycled electrode shows that the NaBPh4 is not decomposed during the cycle and that solid electrolyte interphase (SEI) is derived from DME. Hence, fluorine-based components are not indispensable to stabilize the hard carbon/electrolyte interface. The DME-derived SEI, though containing no F component, can highly stabilize the interface to enable the reversible and high-rate cycling of hard carbon.
topic sodium-ion batteries
hard carbon
electrolyte
fluorine
url https://www.jstage.jst.go.jp/article/electrochemistry/88/3/88_19-00073/_pdf/-char/en
work_keys_str_mv AT yusukemorikawa reversibleandhighratehardcarbonnegativeelectrodesinafluorinefreesodiumsaltelectrolyte
AT yukiyamada reversibleandhighratehardcarbonnegativeelectrodesinafluorinefreesodiumsaltelectrolyte
AT kyosukedoi reversibleandhighratehardcarbonnegativeelectrodesinafluorinefreesodiumsaltelectrolyte
AT shinichinishimura reversibleandhighratehardcarbonnegativeelectrodesinafluorinefreesodiumsaltelectrolyte
AT atsuoyamada reversibleandhighratehardcarbonnegativeelectrodesinafluorinefreesodiumsaltelectrolyte
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