Covalent Benzenesulfonic Functionalization of a Graphene Nanopore for Enhanced and Selective Proton Transport

Calvani, Dario; Kreupeling, Bas; Sevink, G. J. Agur; de Groot, Huub J. M.; Schneider, Grégory F.; Buda, Francesco

doi:10.1021/acs.jpcc.3c07406

Cited by 3 publications

References 70 publications

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Modulation of Proton Permeation through Defect Engineering in Hexagonal Boron Nitride

Rayabharam,

Aluru

2024

J. Phys. Chem. C

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Proton tunneling through 2D materials such as graphene and hexagonal boron nitride (hBN) was demonstrated experimentally in 2014 and has garnered significant attention in the field of nanotechnology due to its potential applications in energy storage, fuel cells, catalysis, and hydrogen isotope separation. Furthermore, engineering defects on similar 2D materials have also contributed to advancing the realization of these applications. Here, we investigate proton tunneling through hBN to improve our understanding of how engineering defects in hBN can be used to modulate proton permeation. Specifically, we employ a 1D transition state model to simulate the permeation of protons through both pristine and defective hBN. This model utilizes the energy barriers of protons permeating across hBN to estimate transmission coefficients, tunneling probabilities, and fluxes. To enhance the accuracy of our flux estimates, we take into account the zero-point energies of protons in water and discuss a method to increase the proton flux through hBN by exciting protons vibrationally. After the incorporation of zero-point energies, our flux calculations indicate that the isotopes of hydrogen ions can be separated at low temperatures using engineered defects in hBN. The results of this study provide insights into engineering defects on hBN, which can lead to the development of membranes with high proton conductivity while remaining impermeable to other species. These findings have significant implications for the design and optimization of advanced materials for various nanoscale applications.

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Modulation of Proton Permeation through Defect Engineering in Hexagonal Boron Nitride

Rayabharam,

Aluru

2024

J. Phys. Chem. C

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Hydrogen Bond Network Shaping Proton Penetration Behavior across Two-Dimensional Nanoporous Materials

Qiao,

Ying,

Zhou

et al. 2024

ACS Appl. Mater. Interfaces

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In this study, we investigate aqueous proton penetration behavior across four types of two-dimensional (2D) nanoporous materials with similar pore sizes using extensive ReaxFF molecular dynamics simulations. The results reveal significant differences in proton penetration energy barriers among the four kinds of 2D materials, despite their comparable pore sizes. Our analysis indicates that these variations in energy barriers stem from differences in the hydrogen bond (HB) network formed between the 2D nanoporous materials and the aqueous environment. The HB network can be classified into two categories: those formed between the surface of the 2D nanoporous materials and the aqueous environment, and those formed between the edge atoms of the nanopores and the water molecules inside the pores. A strong HB network formed between the surface of the 2D nanoporous materials and the aqueous environment induces an orientational preference of water molecules, resulting in an aggregated water layer with high density. This high-density water region traps protons, making it difficult for them to escape and penetrate the nanopores. On the other hand, a strong HB network formed between the edge atoms of the nanopores and the water molecules inside the pores impedes the rotation and migration of water molecules, further inhibiting proton penetration behavior. To facilitate the proton penetration process, in addition to a sufficiently large pore size, a weak HB network between the 2D nanoporous material and the aqueous environment is necessary.

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Sulfophenylated centimeter-size graphene membrane in a direct methanol fuel cell

Schneider,

Zhang,

Makurat

et al. 2024

Preprint

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An ideal proton exchange membrane should only permeate protons and be leak-tight for fuels. Graphene is impermeable to water and poorly conducting to protons. Next to long-term stability an ideal and optimized proton exchange membrane therefore needs to fulfil two main criteria: proton permeability and selectivity. Within methanol fuel cells, the first ensures a high-power density, while the second prevents fuel cross-over between the electrodes, which deteriorates catalyst performance and, thereby, drastically lowers performance. However, proton conductivity and selectivity are antagonistic in polymer membranes concerning their performance1. Long channel length in state-of-the-art membranes such as Nafion 117 is therefore a prerequisite to obtaining proton selectivity, at the cost of an additional ionic resistance through such long channels. Pristine graphene2 already fulfils these two criteria, partly as the graphene basal plane is impermeable to water and other molecules3, and exhibits a certain degree of proton conductivity4, influenced by nanoscaled ripples5, corrugations6, particularly in monolayer graphene oxide7 and hydrogenated graphene8. Here, we chemically functionalized monolayer graphene to install sulfophenylated sp3 dislocations by diazotization. Selective to protons, transmembrane areal conductances surpass those of polymer membranes, while providing proton selectivity over methanol through such an atomically thin layer. By creating proton-conductive and selective paths through graphene, we unveil a covalent chemical route to rationalize transmembrane proton transport through 2D materials.

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Covalent Benzenesulfonic Functionalization of a Graphene Nanopore for Enhanced and Selective Proton Transport

Cited by 3 publications

References 70 publications

Modulation of Proton Permeation through Defect Engineering in Hexagonal Boron Nitride

Modulation of Proton Permeation through Defect Engineering in Hexagonal Boron Nitride

Hydrogen Bond Network Shaping Proton Penetration Behavior across Two-Dimensional Nanoporous Materials

Sulfophenylated centimeter-size graphene membrane in a direct methanol fuel cell

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