Multifunctional intercalants create stable subnanochannels in MoS2 membranes for wastewater treatment

Zhang, Hao; Yong, Ming; Hu, Ting; Kang, Yuan; Wang, Zhuyuan; Xu, Zhonghao; Li, Xuefeng; Sun, Xin; Guo, Lijun; Sheng, Fangmeng; Zeng, Xiangkang; Li, Zhikao; Li, Xingya; Wang, Huanting; Xu, Tongwen; Zhang, Xiwang

Multifunctional intercalants create stable subnanochannels in MoS2 membranes for wastewater treatment

Hao Zhang, Ming Yong, Ting Hu, Yuan Kang, Zhuyuan Wang, Zhonghao Xu, Xuefeng Li, Xin Sun, Lijun Guo, Fangmeng Sheng, Xiangkang Zeng, Zhikao Li, Xingya Li (), Huanting Wang, Tongwen Xu () and Xiwang Zhang ()
Additional contact information
Hao Zhang: The University of Queensland
Ming Yong: The University of Queensland
Ting Hu: Monash University
Yuan Kang: Monash University
Zhuyuan Wang: The University of Queensland
Zhonghao Xu: The University of Queensland
Xuefeng Li: The University of Queensland
Xin Sun: The University of Queensland
Lijun Guo: The University of Queensland
Fangmeng Sheng: University of Science and Technology of China
Xiangkang Zeng: The University of Queensland
Zhikao Li: Monash University
Xingya Li: University of Science and Technology of China
Huanting Wang: Monash University
Tongwen Xu: University of Science and Technology of China
Xiwang Zhang: The University of Queensland

Nature Communications, 2025, vol. 16, issue 1, 1-10

Abstract: Abstract MoS2 nanosheets, featuring high chemical and mechanical stability, offer immense promise as building blocks for high-performance two-dimensional (2D) membranes. However, engineering these membranes to achieve tailored channel dimensions and chemistry while maintaining sufficient stability remains a significant challenge, impeding their real-world applications. Herein, we demonstrate the multifunctionality of polymeric quaternary ammoniums as intercalants in MoS2 membranes, enabling the creation of selective, stable 2D subnanochannels in MoS2 membranes. These intercalants fulfil three key roles: they define and secure the channel width at ~5 Å without disrupting the channel order, impart substantial positive charges to regulate the microenvironment within the channel, and establish strong non-covalent interactions with the electron-rich MoS2 planes to stabilize the channels. Consequently, the resulting membranes exhibit superior stability across various aqueous environments, particularly showing excellent tolerance under highly acidic (1 M H2SO4) conditions. During harsh pressure-driven crossflow operations, the membranes demonstrate fast water permeation while maintaining high rejection (> 90%) and selectivity for heavy metal ions in acidic wastewater. This strategy of leveraging multifunctional intercalants offers critical insights for the design of task-specific 2D membranes for demanding applications.

Date: 2025
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DOI: 10.1038/s41467-025-58409-x

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