Two-dimensional MXene membranes with biomimetic sub-nanochannels for enhanced cation sieving

Rongming Xu; Yuan Kang; Weiming Zhang; Bingcai Pan; Xiwang Zhang

doi:10.1038/s41467-023-40742-8

Two-dimensional MXene membranes with biomimetic sub-nanochannels for enhanced cation sieving

Rongming Xu, Yuan Kang, Weiming Zhang, Bingcai Pan, Xiwang Zhang

Chemical & Biological Engineering

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

87 Citations (Scopus)

Abstract

Membranes with high ion permeability and selectivity are of considerable interest for sustainable water treatment, resource extraction and energy storage. Herein, inspired by K⁺ channel of streptomyces A (KcsA K⁺), we have constructed cation sieving membranes using MXene nanosheets and Ethylenediaminetetraacetic acid (EDTA) molecules as building blocks. Numerous negatively charged oxygen atoms of EDTA molecules and 6.0 Å two-dimensional (2D) sub-nanochannel of MXene nanosheets enable biomimetic channel size, chemical groups and tunable charge density for the resulting membranes. The membranes show the capability to recognize monovalent/divalent cations, achieving excellent K⁺/Mg²⁺ selectivity of 121.2 using mixed salt solution as the feed, which outperforms other reported membranes under similar testing conditions and transcends the current upper limit. Characterization and simulations indicate that the cation recognition effect of EDTA and partial dehydration effects play critical roles in cations selective sieving and increasing the local charge density within the sub-nanochannel significantly improves cation selectivity. Our findings provide a theoretical basis for ions transport in sub-nanochannels and an alternative strategy for design ions separation membranes.

Original language	English
Article number	4907
Number of pages	10
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-40742-8
Publication status	Published - 15 Aug 2023

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10.1038/s41467-023-40742-8Licence: CC BY

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title = "Two-dimensional MXene membranes with biomimetic sub-nanochannels for enhanced cation sieving",

abstract = "Membranes with high ion permeability and selectivity are of considerable interest for sustainable water treatment, resource extraction and energy storage. Herein, inspired by K+ channel of streptomyces A (KcsA K+), we have constructed cation sieving membranes using MXene nanosheets and Ethylenediaminetetraacetic acid (EDTA) molecules as building blocks. Numerous negatively charged oxygen atoms of EDTA molecules and 6.0 {\AA} two-dimensional (2D) sub-nanochannel of MXene nanosheets enable biomimetic channel size, chemical groups and tunable charge density for the resulting membranes. The membranes show the capability to recognize monovalent/divalent cations, achieving excellent K+/Mg2+ selectivity of 121.2 using mixed salt solution as the feed, which outperforms other reported membranes under similar testing conditions and transcends the current upper limit. Characterization and simulations indicate that the cation recognition effect of EDTA and partial dehydration effects play critical roles in cations selective sieving and increasing the local charge density within the sub-nanochannel significantly improves cation selectivity. Our findings provide a theoretical basis for ions transport in sub-nanochannels and an alternative strategy for design ions separation membranes.",

author = "Rongming Xu and Yuan Kang and Weiming Zhang and Bingcai Pan and Xiwang Zhang",

note = "Funding Information: This work was financially supported by the National Key R&D Program of China (2021YFA1201700, W.Z.), National Natural Science Foundation of China (U22A20403, W.Z.), Australian Research Council for funding the Industry Transformation Research Hub for Energy-efficient Separation (IH170100009, X.Z.) and Australian Research Council ARC Future Fellowship (FT210100593, X.Z.). The authors thank Sikai Cheng, Ruolin Lv and Mingyang Li for their assistance in ultrathin section for membrane cross-section TEM images, XPS measurements and DFT calculations, respectively. The authors thank the High-Performance Computing Center (HPCC) of Nanjing University for using the computation resources. Funding Information: This work was financially supported by the National Key R&D Program of China (2021YFA1201700, W.Z.), National Natural Science Foundation of China (U22A20403, W.Z.), Australian Research Council for funding the Industry Transformation Research Hub for Energy-efficient Separation (IH170100009, X.Z.) and Australian Research Council ARC Future Fellowship (FT210100593, X.Z.). The authors thank Sikai Cheng, Ruolin Lv and Mingyang Li for their assistance in ultrathin section for membrane cross-section TEM images, XPS measurements and DFT calculations, respectively. The authors thank the High-Performance Computing Center (HPCC) of Nanjing University for using the computation resources. Publisher Copyright: {\textcopyright} 2023, Springer Nature Limited.",

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doi = "10.1038/s41467-023-40742-8",

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AU - Zhang, Xiwang

N1 - Funding Information: This work was financially supported by the National Key R&D Program of China (2021YFA1201700, W.Z.), National Natural Science Foundation of China (U22A20403, W.Z.), Australian Research Council for funding the Industry Transformation Research Hub for Energy-efficient Separation (IH170100009, X.Z.) and Australian Research Council ARC Future Fellowship (FT210100593, X.Z.). The authors thank Sikai Cheng, Ruolin Lv and Mingyang Li for their assistance in ultrathin section for membrane cross-section TEM images, XPS measurements and DFT calculations, respectively. The authors thank the High-Performance Computing Center (HPCC) of Nanjing University for using the computation resources. Funding Information: This work was financially supported by the National Key R&D Program of China (2021YFA1201700, W.Z.), National Natural Science Foundation of China (U22A20403, W.Z.), Australian Research Council for funding the Industry Transformation Research Hub for Energy-efficient Separation (IH170100009, X.Z.) and Australian Research Council ARC Future Fellowship (FT210100593, X.Z.). The authors thank Sikai Cheng, Ruolin Lv and Mingyang Li for their assistance in ultrathin section for membrane cross-section TEM images, XPS measurements and DFT calculations, respectively. The authors thank the High-Performance Computing Center (HPCC) of Nanjing University for using the computation resources. Publisher Copyright: © 2023, Springer Nature Limited.

PY - 2023/8/15

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N2 - Membranes with high ion permeability and selectivity are of considerable interest for sustainable water treatment, resource extraction and energy storage. Herein, inspired by K+ channel of streptomyces A (KcsA K+), we have constructed cation sieving membranes using MXene nanosheets and Ethylenediaminetetraacetic acid (EDTA) molecules as building blocks. Numerous negatively charged oxygen atoms of EDTA molecules and 6.0 Å two-dimensional (2D) sub-nanochannel of MXene nanosheets enable biomimetic channel size, chemical groups and tunable charge density for the resulting membranes. The membranes show the capability to recognize monovalent/divalent cations, achieving excellent K+/Mg2+ selectivity of 121.2 using mixed salt solution as the feed, which outperforms other reported membranes under similar testing conditions and transcends the current upper limit. Characterization and simulations indicate that the cation recognition effect of EDTA and partial dehydration effects play critical roles in cations selective sieving and increasing the local charge density within the sub-nanochannel significantly improves cation selectivity. Our findings provide a theoretical basis for ions transport in sub-nanochannels and an alternative strategy for design ions separation membranes.

AB - Membranes with high ion permeability and selectivity are of considerable interest for sustainable water treatment, resource extraction and energy storage. Herein, inspired by K+ channel of streptomyces A (KcsA K+), we have constructed cation sieving membranes using MXene nanosheets and Ethylenediaminetetraacetic acid (EDTA) molecules as building blocks. Numerous negatively charged oxygen atoms of EDTA molecules and 6.0 Å two-dimensional (2D) sub-nanochannel of MXene nanosheets enable biomimetic channel size, chemical groups and tunable charge density for the resulting membranes. The membranes show the capability to recognize monovalent/divalent cations, achieving excellent K+/Mg2+ selectivity of 121.2 using mixed salt solution as the feed, which outperforms other reported membranes under similar testing conditions and transcends the current upper limit. Characterization and simulations indicate that the cation recognition effect of EDTA and partial dehydration effects play critical roles in cations selective sieving and increasing the local charge density within the sub-nanochannel significantly improves cation selectivity. Our findings provide a theoretical basis for ions transport in sub-nanochannels and an alternative strategy for design ions separation membranes.

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Two-dimensional MXene membranes with biomimetic sub-nanochannels for enhanced cation sieving

Abstract

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ARC Research Hub for Energy-efficient Separation

Epitaxial Stacking of Nanoporous Nanosheets for Next-generation Membranes

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Two-dimensional MXene membranes with biomimetic sub-nanochannels for enhanced cation sieving

Abstract

Access to Document

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Projects

ARC Research Hub for Energy-efficient Separation

Epitaxial Stacking of Nanoporous Nanosheets for Next-generation Membranes

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