Ion-Specific Nanoconfinement Effect in Multilayered Graphene Membranes: A Combined Nuclear Magnetic Resonance and Computational Study

Diyan Liu; Zhiyuan Xiong; Peiyao Wang; Qinghua Liang; Haijin Zhu; Jefferson Zhe Liu; Maria Forsyth; Dan Li

doi:10.1021/acs.nanolett.3c00877

Ion-Specific Nanoconfinement Effect in Multilayered Graphene Membranes: A Combined Nuclear Magnetic Resonance and Computational Study

Diyan Liu, Zhiyuan Xiong, Peiyao Wang, Qinghua Liang, Haijin Zhu^*, Jefferson Zhe Liu, Maria Forsyth, Dan Li^*

^*Corresponding author for this work

Materials Science and Engineering

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

Abstract

Ion adsorption within nanopores is involved in numerous applications. However, a comprehensive understanding of the fundamental relationship between in-pore ion concentration and pore size, particularly in the sub-2 nm range, is scarce. This study investigates the ion-species-dependent concentration in multilayered graphene membranes (MGMs) with tunable nanoslit sizes (0.5–1.6 nm) using nuclear magnetic resonance and computational simulations. For Na+-based electrolytes in MGMs, the concentration of anions in graphene nanoslits increases in correlation with their chaotropic properties. As the nanoslit size decreases, the concentration of chaotropic ion (BF4–) increases, whereas the concentration of kosmotropic ions (Cit3–, PO43–) and other ions (Ac–, F–) decreases or changes slightly. Notably, anions remain more concentrated than counter Na+ ions, leading to electroneutrality breakdown and unipolar anion packing in MGMs. A continuum modeling approach, integrating molecular dynamic simulation with the Poisson–Boltzmann model, elucidates these observations by considering water-mediated ion–graphene non-electrostatic interactions and charge screening from graphene walls.

Original language	English
Journal	Nano Letters
DOIs	https://doi.org/10.1021/acs.nanolett.3c00877
State	Published - 14 Jun 2023

Keywords

nanoconfinement
ion-specific effect
electroneutrality breakdown
graphene membrane
nuclear magnetic resonance

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10.1021/acs.nanolett.3c00877

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title = "Ion-Specific Nanoconfinement Effect in Multilayered Graphene Membranes: A Combined Nuclear Magnetic Resonance and Computational Study",

abstract = "Ion adsorption within nanopores is involved in numerous applications. However, a comprehensive understanding of the fundamental relationship between in-pore ion concentration and pore size, particularly in the sub-2 nm range, is scarce. This study investigates the ion-species-dependent concentration in multilayered graphene membranes (MGMs) with tunable nanoslit sizes (0.5–1.6 nm) using nuclear magnetic resonance and computational simulations. For Na+-based electrolytes in MGMs, the concentration of anions in graphene nanoslits increases in correlation with their chaotropic properties. As the nanoslit size decreases, the concentration of chaotropic ion (BF4–) increases, whereas the concentration of kosmotropic ions (Cit3–, PO43–) and other ions (Ac–, F–) decreases or changes slightly. Notably, anions remain more concentrated than counter Na+ ions, leading to electroneutrality breakdown and unipolar anion packing in MGMs. A continuum modeling approach, integrating molecular dynamic simulation with the Poisson–Boltzmann model, elucidates these observations by considering water-mediated ion–graphene non-electrostatic interactions and charge screening from graphene walls.",

keywords = "nanoconfinement, ion-specific effect, electroneutrality breakdown, graphene membrane, nuclear magnetic resonance",

author = "Diyan Liu and Zhiyuan Xiong and Peiyao Wang and Qinghua Liang and Haijin Zhu and Liu, {Jefferson Zhe} and Maria Forsyth and Dan Li",

year = "2023",

month = jun,

day = "14",

doi = "10.1021/acs.nanolett.3c00877",

language = "英语",

journal = "Nano Letters",

issn = "1530-6984",

publisher = "American Chemical Society",

}

TY - JOUR

T1 - Ion-Specific Nanoconfinement Effect in Multilayered Graphene Membranes: A Combined Nuclear Magnetic Resonance and Computational Study

AU - Liu, Diyan

AU - Xiong, Zhiyuan

AU - Wang, Peiyao

AU - Liang, Qinghua

AU - Zhu, Haijin

AU - Liu, Jefferson Zhe

AU - Forsyth, Maria

AU - Li, Dan

PY - 2023/6/14

Y1 - 2023/6/14

N2 - Ion adsorption within nanopores is involved in numerous applications. However, a comprehensive understanding of the fundamental relationship between in-pore ion concentration and pore size, particularly in the sub-2 nm range, is scarce. This study investigates the ion-species-dependent concentration in multilayered graphene membranes (MGMs) with tunable nanoslit sizes (0.5–1.6 nm) using nuclear magnetic resonance and computational simulations. For Na+-based electrolytes in MGMs, the concentration of anions in graphene nanoslits increases in correlation with their chaotropic properties. As the nanoslit size decreases, the concentration of chaotropic ion (BF4–) increases, whereas the concentration of kosmotropic ions (Cit3–, PO43–) and other ions (Ac–, F–) decreases or changes slightly. Notably, anions remain more concentrated than counter Na+ ions, leading to electroneutrality breakdown and unipolar anion packing in MGMs. A continuum modeling approach, integrating molecular dynamic simulation with the Poisson–Boltzmann model, elucidates these observations by considering water-mediated ion–graphene non-electrostatic interactions and charge screening from graphene walls.

AB - Ion adsorption within nanopores is involved in numerous applications. However, a comprehensive understanding of the fundamental relationship between in-pore ion concentration and pore size, particularly in the sub-2 nm range, is scarce. This study investigates the ion-species-dependent concentration in multilayered graphene membranes (MGMs) with tunable nanoslit sizes (0.5–1.6 nm) using nuclear magnetic resonance and computational simulations. For Na+-based electrolytes in MGMs, the concentration of anions in graphene nanoslits increases in correlation with their chaotropic properties. As the nanoslit size decreases, the concentration of chaotropic ion (BF4–) increases, whereas the concentration of kosmotropic ions (Cit3–, PO43–) and other ions (Ac–, F–) decreases or changes slightly. Notably, anions remain more concentrated than counter Na+ ions, leading to electroneutrality breakdown and unipolar anion packing in MGMs. A continuum modeling approach, integrating molecular dynamic simulation with the Poisson–Boltzmann model, elucidates these observations by considering water-mediated ion–graphene non-electrostatic interactions and charge screening from graphene walls.

KW - nanoconfinement

KW - ion-specific effect

KW - electroneutrality breakdown

KW - graphene membrane

KW - nuclear magnetic resonance

U2 - 10.1021/acs.nanolett.3c00877

DO - 10.1021/acs.nanolett.3c00877

M3 - 文章

SN - 1530-6984

JO - Nano Letters

JF - Nano Letters

ER -

Ion-Specific Nanoconfinement Effect in Multilayered Graphene Membranes: A Combined Nuclear Magnetic Resonance and Computational Study

Abstract

Keywords

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