Surface-functionalized boron nanosheets and their assembled suprastructures with unprecedented proton-transport properties

Hongfeng Zhan; Mengwei Dong; Shengchuang Qiu; Xiaoshan Wang; Lingfeng Chao; Zhendong Huang; Yonghua Chen; Hai Li; Xiao Huang; Shaozhou Li

doi:10.1039/d3cc02537c

Surface-functionalized boron nanosheets and their assembled suprastructures with unprecedented proton-transport properties

Hongfeng Zhan, Mengwei Dong, Shengchuang Qiu, Xiaoshan Wang, Lingfeng Chao, Zhendong Huang, Yonghua Chen, Hai Li, Xiao Huang, Shaozhou Li

SCHOOL OF FLEXIBLE ELECTRONICS(FUTURE TECHNOLOGIES)|INSTITUTE OF ADVANCED MATERIALS(IAM)

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

2 Scopus citations

Abstract

Two-dimensional (2D) boron nanomaterials have received considerable attention due to their distinct physicochemical properties in contrast to bulk boron. However, the susceptibility to oxidation in air has limited their practical applications. In this study, we synthesize an environmentally stable bifunctionalized boron nanosheet via a wet chemical route. By lyophilization, we have hierarchically assembled the boron nanosheets into various well-ordered macroscopic forms, which exhibit unique structural features, such as stacking-induced nanochannels for proton transport. The resulting suprastructures show exceptionally high proton conductivity (∼90 mS cm⁻¹ at 85 °C) and humidity sensitivity (response >40 000% at 97% RH). These findings demonstrate the immense potential of boron nanomaterials in electrochemical applications.

Original language	English
Pages (from-to)	9730-9733
Number of pages	4
Journal	Chemical Communications
Volume	59
Issue number	64
DOIs	https://doi.org/10.1039/d3cc02537c
State	Published - 17 Jul 2023

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title = "Surface-functionalized boron nanosheets and their assembled suprastructures with unprecedented proton-transport properties",

abstract = "Two-dimensional (2D) boron nanomaterials have received considerable attention due to their distinct physicochemical properties in contrast to bulk boron. However, the susceptibility to oxidation in air has limited their practical applications. In this study, we synthesize an environmentally stable bifunctionalized boron nanosheet via a wet chemical route. By lyophilization, we have hierarchically assembled the boron nanosheets into various well-ordered macroscopic forms, which exhibit unique structural features, such as stacking-induced nanochannels for proton transport. The resulting suprastructures show exceptionally high proton conductivity (∼90 mS cm−1 at 85 °C) and humidity sensitivity (response >40 000% at 97% RH). These findings demonstrate the immense potential of boron nanomaterials in electrochemical applications.",

author = "Hongfeng Zhan and Mengwei Dong and Shengchuang Qiu and Xiaoshan Wang and Lingfeng Chao and Zhendong Huang and Yonghua Chen and Hai Li and Xiao Huang and Shaozhou Li",

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T1 - Surface-functionalized boron nanosheets and their assembled suprastructures with unprecedented proton-transport properties

AU - Zhan, Hongfeng

AU - Dong, Mengwei

AU - Qiu, Shengchuang

AU - Wang, Xiaoshan

AU - Chao, Lingfeng

AU - Huang, Zhendong

AU - Chen, Yonghua

AU - Li, Hai

AU - Huang, Xiao

AU - Li, Shaozhou

PY - 2023/7/17

Y1 - 2023/7/17

N2 - Two-dimensional (2D) boron nanomaterials have received considerable attention due to their distinct physicochemical properties in contrast to bulk boron. However, the susceptibility to oxidation in air has limited their practical applications. In this study, we synthesize an environmentally stable bifunctionalized boron nanosheet via a wet chemical route. By lyophilization, we have hierarchically assembled the boron nanosheets into various well-ordered macroscopic forms, which exhibit unique structural features, such as stacking-induced nanochannels for proton transport. The resulting suprastructures show exceptionally high proton conductivity (∼90 mS cm−1 at 85 °C) and humidity sensitivity (response >40 000% at 97% RH). These findings demonstrate the immense potential of boron nanomaterials in electrochemical applications.

AB - Two-dimensional (2D) boron nanomaterials have received considerable attention due to their distinct physicochemical properties in contrast to bulk boron. However, the susceptibility to oxidation in air has limited their practical applications. In this study, we synthesize an environmentally stable bifunctionalized boron nanosheet via a wet chemical route. By lyophilization, we have hierarchically assembled the boron nanosheets into various well-ordered macroscopic forms, which exhibit unique structural features, such as stacking-induced nanochannels for proton transport. The resulting suprastructures show exceptionally high proton conductivity (∼90 mS cm−1 at 85 °C) and humidity sensitivity (response >40 000% at 97% RH). These findings demonstrate the immense potential of boron nanomaterials in electrochemical applications.

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U2 - 10.1039/d3cc02537c

DO - 10.1039/d3cc02537c

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SP - 9730

EP - 9733

JO - Chemical Communications

JF - Chemical Communications

IS - 64

ER -

Surface-functionalized boron nanosheets and their assembled suprastructures with unprecedented proton-transport properties

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