Marangoni-Driven Self-Assembly MXene As Functional Membrane Enables Dendrite-Free and Flexible Zinc–Iodine Pouch Cells

Huan Liu; Zhijing Xu; Bin Cao; Zijun Xin; Hongjuan Lai; Shan Gao; Bin Xu; Jin Lin Yang; Tao Xiao; Bao Zhang; Hong Jin Fan

doi:10.1002/aenm.202400318

Marangoni-Driven Self-Assembly MXene As Functional Membrane Enables Dendrite-Free and Flexible Zinc–Iodine Pouch Cells

Huan Liu, Zhijing Xu, Bin Cao^*, Zijun Xin, Hongjuan Lai, Shan Gao, Bin Xu^*, Jin Lin Yang, Tao Xiao, Bao Zhang, Hong Jin Fan^*

^*Corresponding author for this work

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

63 Citations (Scopus)

Abstract

Zn metal is a promising anode material in aqueous batteries, but the direct use of Zn foil encounters severe issues of dendrite formation and side reactions, causing short cycle life. Conventional thick and rigid insulating protection layers may impede Zn ion diffusion and detach during mechanical deformation of the battery. Herein, a dendrite-free zinc anode is demonstrated by grafting a thin (≈10 nm) Ti₃C₂T_x MXene functional membrane which is formed via Marangoni-driven self-assembly. The thin MXene membrane initiates uniform nucleation and promotes deposition of (002)-oriented Zn in a lateral growth mode. Meanwhile, the membrane functions as a soft, stress-adaptive, and protective layer to the underneath active zinc. This functional membrane renders Zn anode with improved cycling stability without notable dendrite formation or side-reaction products. Flexible Zn─I₂ pouch cells fabricated from the MXene-covered Zn foil (20 µm thick) anode and a modified ZnI₂ cathode demonstrate stable capacity up to 1500 cycles and unchanged voltage upon various mechanical deformations. This work affords new insights into designing functional soft membranes for constructing flexible Zn-based energy devices.

Original language	English
Article number	2400318
Journal	Advanced Energy Materials
Volume	14
Issue number	26
DOIs	https://doi.org/10.1002/aenm.202400318
Publication status	Published - Jul 12 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2024 Wiley-VCH GmbH.

ASJC Scopus Subject Areas

Renewable Energy, Sustainability and the Environment
General Materials Science

Keywords

anode surface protection
flexible cell
MXene membrane
stress release
zinc–iodine battery

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/aenm.202400318

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title = "Marangoni-Driven Self-Assembly MXene As Functional Membrane Enables Dendrite-Free and Flexible Zinc–Iodine Pouch Cells",

abstract = "Zn metal is a promising anode material in aqueous batteries, but the direct use of Zn foil encounters severe issues of dendrite formation and side reactions, causing short cycle life. Conventional thick and rigid insulating protection layers may impede Zn ion diffusion and detach during mechanical deformation of the battery. Herein, a dendrite-free zinc anode is demonstrated by grafting a thin (≈10 nm) Ti3C2Tx MXene functional membrane which is formed via Marangoni-driven self-assembly. The thin MXene membrane initiates uniform nucleation and promotes deposition of (002)-oriented Zn in a lateral growth mode. Meanwhile, the membrane functions as a soft, stress-adaptive, and protective layer to the underneath active zinc. This functional membrane renders Zn anode with improved cycling stability without notable dendrite formation or side-reaction products. Flexible Zn─I2 pouch cells fabricated from the MXene-covered Zn foil (20 µm thick) anode and a modified ZnI2 cathode demonstrate stable capacity up to 1500 cycles and unchanged voltage upon various mechanical deformations. This work affords new insights into designing functional soft membranes for constructing flexible Zn-based energy devices.",

keywords = "anode surface protection, flexible cell, MXene membrane, stress release, zinc–iodine battery",

author = "Huan Liu and Zhijing Xu and Bin Cao and Zijun Xin and Hongjuan Lai and Shan Gao and Bin Xu and Yang, {Jin Lin} and Tao Xiao and Bao Zhang and Fan, {Hong Jin}",

note = "Publisher Copyright: {\textcopyright} 2024 Wiley-VCH GmbH.",

year = "2024",

month = jul,

day = "12",

doi = "10.1002/aenm.202400318",

language = "English",

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T1 - Marangoni-Driven Self-Assembly MXene As Functional Membrane Enables Dendrite-Free and Flexible Zinc–Iodine Pouch Cells

AU - Liu, Huan

AU - Xu, Zhijing

AU - Cao, Bin

AU - Xin, Zijun

AU - Lai, Hongjuan

AU - Gao, Shan

AU - Xu, Bin

AU - Yang, Jin Lin

AU - Xiao, Tao

AU - Zhang, Bao

AU - Fan, Hong Jin

PY - 2024/7/12

Y1 - 2024/7/12

N2 - Zn metal is a promising anode material in aqueous batteries, but the direct use of Zn foil encounters severe issues of dendrite formation and side reactions, causing short cycle life. Conventional thick and rigid insulating protection layers may impede Zn ion diffusion and detach during mechanical deformation of the battery. Herein, a dendrite-free zinc anode is demonstrated by grafting a thin (≈10 nm) Ti3C2Tx MXene functional membrane which is formed via Marangoni-driven self-assembly. The thin MXene membrane initiates uniform nucleation and promotes deposition of (002)-oriented Zn in a lateral growth mode. Meanwhile, the membrane functions as a soft, stress-adaptive, and protective layer to the underneath active zinc. This functional membrane renders Zn anode with improved cycling stability without notable dendrite formation or side-reaction products. Flexible Zn─I2 pouch cells fabricated from the MXene-covered Zn foil (20 µm thick) anode and a modified ZnI2 cathode demonstrate stable capacity up to 1500 cycles and unchanged voltage upon various mechanical deformations. This work affords new insights into designing functional soft membranes for constructing flexible Zn-based energy devices.

AB - Zn metal is a promising anode material in aqueous batteries, but the direct use of Zn foil encounters severe issues of dendrite formation and side reactions, causing short cycle life. Conventional thick and rigid insulating protection layers may impede Zn ion diffusion and detach during mechanical deformation of the battery. Herein, a dendrite-free zinc anode is demonstrated by grafting a thin (≈10 nm) Ti3C2Tx MXene functional membrane which is formed via Marangoni-driven self-assembly. The thin MXene membrane initiates uniform nucleation and promotes deposition of (002)-oriented Zn in a lateral growth mode. Meanwhile, the membrane functions as a soft, stress-adaptive, and protective layer to the underneath active zinc. This functional membrane renders Zn anode with improved cycling stability without notable dendrite formation or side-reaction products. Flexible Zn─I2 pouch cells fabricated from the MXene-covered Zn foil (20 µm thick) anode and a modified ZnI2 cathode demonstrate stable capacity up to 1500 cycles and unchanged voltage upon various mechanical deformations. This work affords new insights into designing functional soft membranes for constructing flexible Zn-based energy devices.

KW - anode surface protection

KW - flexible cell

KW - MXene membrane

KW - stress release

KW - zinc–iodine battery

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Marangoni-Driven Self-Assembly MXene As Functional Membrane Enables Dendrite-Free and Flexible Zinc–Iodine Pouch Cells

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

UN SDGs

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