Confining Aqueous Zn–Br Halide Redox Chemistry by Ti3C2TX MXene

Xinliang LI; Na LI; Zhaodong HUANG; Ze CHEN; Yuwei ZHAO; Guojin LIANG; Qi YANG; Mian LI; Qing HUANG; Binbin DONG; Jun FAN; Chunyi ZHI

doi:10.1021/acsnano.0c09380

Confining Aqueous Zn–Br Halide Redox Chemistry by Ti₃C₂T_X MXene

Xinliang LI, Na LI, Zhaodong HUANG, Ze CHEN, Yuwei ZHAO, Guojin LIANG, Qi YANG, Mian LI, Qing HUANG, Binbin DONG, Jun FAN^*, Chunyi ZHI^*

^*Corresponding author for this work

Research output: Journal Publications › Journal Article (refereed) › peer-review

105 Citations (Scopus)

Abstract

With fluidity and dangerous corrosiveness, liquid insulating bromine elemental (Br₂) can hardly be confined by traditional conductive carriers (mainly carbon materials) for efficient redox without shuttle behavior. Thus, stationary Br₂-based energy storage devices are rarely advanced. Here, we introduce an electrochemical active parasite Br₂ to the Ti₃C₂T_XMXene host and construct an advanced aqueous zinc redox battery via a facile electrodeposition process (Br-Ti₃C₂T_X). Both ex situ experimental characterizations and density functional theory (DFT) simulations have validated the natural affinity between MXenes and Br species, which is manifested as their spontaneous fixation accompanied by rapid transfer of electrons in the interface region and interlayer confinement. Consequently, the battery delivers a high-voltage plateau at 1.75 V that contributes to an improved energy density of 259 Wh kg^–1_Br (144 Wh kg^–1_Br-Ti3C₂T_X), exhibiting efficient output capability in the high-voltage region. Besides, benefiting from enhanced redox kinetics, the capacity achieved at −15 °C approaches to 69% of the value at room temperature. More importantly, an excellent 10 000 cycles at −15 °C with negligible capacity decay is identified. The paradigm represents a step forward for developing stationary aqueous metal-Br₂ batteries.

Original language	English
Pages (from-to)	1718-1726
Number of pages	9
Journal	ACS Nano
Volume	15
Issue number	1
Early online date	13 Jan 2021
DOIs	https://doi.org/10.1021/acsnano.0c09380
Publication status	Published - 26 Jan 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021 American Chemical Society.

Funding

This research was supported by the National Key R&D Program of China under Project 2019YFA0705104. H.Q. thank supports of Leading Innovative and Entrepreneur Team Introduction Program of Zhejiang (Grant No. 2019R01003).

Keywords

DFT simulation
Ti C T MXene
confinement effect
electrodeposition
halogen-Zn battery

Access to Document

10.1021/acsnano.0c09380

Cite this

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title = "Confining Aqueous Zn–Br Halide Redox Chemistry by Ti3C2TX MXene",

abstract = "With fluidity and dangerous corrosiveness, liquid insulating bromine elemental (Br2) can hardly be confined by traditional conductive carriers (mainly carbon materials) for efficient redox without shuttle behavior. Thus, stationary Br2-based energy storage devices are rarely advanced. Here, we introduce an electrochemical active parasite Br2 to the Ti3C2TXMXene host and construct an advanced aqueous zinc redox battery via a facile electrodeposition process (Br-Ti3C2TX). Both ex situ experimental characterizations and density functional theory (DFT) simulations have validated the natural affinity between MXenes and Br species, which is manifested as their spontaneous fixation accompanied by rapid transfer of electrons in the interface region and interlayer confinement. Consequently, the battery delivers a high-voltage plateau at 1.75 V that contributes to an improved energy density of 259 Wh kg–1Br (144 Wh kg–1Br-Ti3C2TX), exhibiting efficient output capability in the high-voltage region. Besides, benefiting from enhanced redox kinetics, the capacity achieved at −15 °C approaches to 69% of the value at room temperature. More importantly, an excellent 10 000 cycles at −15 °C with negligible capacity decay is identified. The paradigm represents a step forward for developing stationary aqueous metal-Br2 batteries.",

keywords = "DFT simulation, Ti C T MXene, confinement effect, electrodeposition, halogen-Zn battery",

author = "Xinliang LI and Na LI and Zhaodong HUANG and Ze CHEN and Yuwei ZHAO and Guojin LIANG and Qi YANG and Mian LI and Qing HUANG and Binbin DONG and Jun FAN and Chunyi ZHI",

note = "Publisher Copyright: {\textcopyright} 2021 American Chemical Society.",

year = "2021",

month = jan,

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doi = "10.1021/acsnano.0c09380",

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TY - JOUR

T1 - Confining Aqueous Zn–Br Halide Redox Chemistry by Ti3C2TX MXene

AU - LI, Xinliang

AU - LI, Na

AU - HUANG, Zhaodong

AU - CHEN, Ze

AU - ZHAO, Yuwei

AU - LIANG, Guojin

AU - YANG, Qi

AU - LI, Mian

AU - HUANG, Qing

AU - DONG, Binbin

AU - FAN, Jun

AU - ZHI, Chunyi

PY - 2021/1/26

Y1 - 2021/1/26

N2 - With fluidity and dangerous corrosiveness, liquid insulating bromine elemental (Br2) can hardly be confined by traditional conductive carriers (mainly carbon materials) for efficient redox without shuttle behavior. Thus, stationary Br2-based energy storage devices are rarely advanced. Here, we introduce an electrochemical active parasite Br2 to the Ti3C2TXMXene host and construct an advanced aqueous zinc redox battery via a facile electrodeposition process (Br-Ti3C2TX). Both ex situ experimental characterizations and density functional theory (DFT) simulations have validated the natural affinity between MXenes and Br species, which is manifested as their spontaneous fixation accompanied by rapid transfer of electrons in the interface region and interlayer confinement. Consequently, the battery delivers a high-voltage plateau at 1.75 V that contributes to an improved energy density of 259 Wh kg–1Br (144 Wh kg–1Br-Ti3C2TX), exhibiting efficient output capability in the high-voltage region. Besides, benefiting from enhanced redox kinetics, the capacity achieved at −15 °C approaches to 69% of the value at room temperature. More importantly, an excellent 10 000 cycles at −15 °C with negligible capacity decay is identified. The paradigm represents a step forward for developing stationary aqueous metal-Br2 batteries.

AB - With fluidity and dangerous corrosiveness, liquid insulating bromine elemental (Br2) can hardly be confined by traditional conductive carriers (mainly carbon materials) for efficient redox without shuttle behavior. Thus, stationary Br2-based energy storage devices are rarely advanced. Here, we introduce an electrochemical active parasite Br2 to the Ti3C2TXMXene host and construct an advanced aqueous zinc redox battery via a facile electrodeposition process (Br-Ti3C2TX). Both ex situ experimental characterizations and density functional theory (DFT) simulations have validated the natural affinity between MXenes and Br species, which is manifested as their spontaneous fixation accompanied by rapid transfer of electrons in the interface region and interlayer confinement. Consequently, the battery delivers a high-voltage plateau at 1.75 V that contributes to an improved energy density of 259 Wh kg–1Br (144 Wh kg–1Br-Ti3C2TX), exhibiting efficient output capability in the high-voltage region. Besides, benefiting from enhanced redox kinetics, the capacity achieved at −15 °C approaches to 69% of the value at room temperature. More importantly, an excellent 10 000 cycles at −15 °C with negligible capacity decay is identified. The paradigm represents a step forward for developing stationary aqueous metal-Br2 batteries.

KW - DFT simulation

KW - Ti C T MXene

KW - confinement effect

KW - electrodeposition

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