Effects of water nanochannel diameter on proton transport in proton‐exchange membranes

Mabuchi, Takuya; Tokumasu, Takashi

doi:10.1002/polb.24842

Cited by 25 publications

(22 citation statements)

References 46 publications

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“…It can also serve as a means for obtaining various unknown physical properties of IPMCs, such as the electro-osmotic drag coefficient of water and dielectric constant. These properties are not readily available experimentally, and, to date, they were computed numerically only for bare membranes, without accounting for metal electrodes [28–30]. Finally, our work can provide a bridge between atomistic and continuum considerations.…”

Section: Discussionmentioning

confidence: 99%

“…Allahyarov and Taylor [23] studied morphological changes of polymeric backbones upon application of electric field with coarse-grained MD, showing the formation of a topology that favours counterions’ transport. Other authors have considered the influence of an external electric field on the membrane structure and mobilities of hydronium counterions [24–28]. Coarse-grained MD simulations of a single ionomer pore with sodium chloride solution and external electric field were used in [29] to compute electro-osmotic drag coefficients, and Mabuchi and Tokumasu [28] performed an analogous analysis for hydronium counterions.…”

Section: Introductionmentioning

confidence: 99%

“…Other authors have considered the influence of an external electric field on the membrane structure and mobilities of hydronium counterions [24–28]. Coarse-grained MD simulations of a single ionomer pore with sodium chloride solution and external electric field were used in [29] to compute electro-osmotic drag coefficients, and Mabuchi and Tokumasu [28] performed an analogous analysis for hydronium counterions. Additionally, Waters et al [30] investigated the influence of an electric field on ionomers with lithium counterion from the perspective of energy, dielectric properties and transport of counterions.…”

Section: Introductionmentioning

confidence: 99%

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Molecular dynamics of ionic polymer-metal composites

Truszkowska

Porfiri

2021

Phil. Trans. R. Soc. A.

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Ionic polymer-metal composites (IPMCs) constitute a promising class of soft, active materials with potentially ubiquitous use in science and engineering. Realizing the full potential of IPMCs calls for a deeper understanding of the mechanisms underpinning their most intriguing characteristics: the ability to deform under an electric field and the generation of a voltage upon mechanical deformation. These behaviours are tightly linked to physical phenomena at the level of atoms, including rearrangements of ions and molecules, along with the formation of sub-nanometre thick double layers on the surface of the metal electrodes. Several continuum theories have been developed to describe these phenomena, but their experimental and theoretical validation remains incomplete. IPMC modelling at the atomistic scale could beget valuable support for these efforts, by affording granular analysis of individual atoms. Here, we present a simplified atomistic model of IPMCs based on classical molecular dynamics. The three-dimensional IPMC membrane is constrained by two smooth walls, a simplified analogue of metal electrodes, impermeable only to counterions. The electric field is applied as an additional force acting on all the atoms. We demonstrate the feasibility of simulating counterions’ migration and pile-up upon the application of an electric field, similar to experimental observations. By analysing the spatial configuration of atoms and stress distribution, we identify two mechanisms for stress generation. The presented model offers new insight into the physical underpinnings of actuation and sensing in IPMCs. This article is part of the theme issue ‘Progress in mesoscale methods for fluid dynamics simulation’.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Molecular dynamics of ionic polymer-metal composites

Truszkowska

Porfiri

2021

Phil. Trans. R. Soc. A.

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“…Theoretically, many molecular dynamics (MD) simulations of PFSA membranes have been performed to study proton and oxygen transport within the morphology of PFSA membranes and ionomer thin films . Most atomistic simulation studies have primarily focused on the solid state of ionomers in PEMs and CLs with a water volume fraction significantly below 50%.…”

Section: Introductionmentioning

confidence: 99%

Nafion Ionomer Dispersion in Mixtures of 1‐Propanol and Water Based on the Martini Coarse‐Grained Model

Mabuchi

Huang

Tokumasu

2020

Journal of Polymer Science

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The self-assembly of Nafion ionomer in a mixture of 1-propanol (NPA) and water was investigated using coarsegrained molecular dynamics simulations. Ionomer formation into cylindrical bundle-like aggregates is observed when the ionomer chain size is sufficiently large. The size of ionomer bundles decreases (the diameter decreased from~2.5 to~1.9 nm) with increasing NPA content, which indicates that the ionomers tend to be more dispersed at higher NPA content. The results of simulations are in good quantitative agreement with the stable size of an ionomer bundle estimated from our free energy calculations as well as the available experimental data. Furthermore, in contrast to the polarizable NPA model, the standard nonpolarizable NPA model shows the opposite trend that the ionomer size increases with increasing NPA content because of a higher localization of hydronium ions at the bundle surface, revealing that the polarization effect plays a significant role in determining the aggregation behaviors. The present study provides insight into the control of ionomer self-assembly toward obtaining targeted structures for specific purposes.

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“…Although the types of macromolecules and ions are different in the present study, in our previous studies, we analyzed the ion transport phenomena in polymer electrolyte membranes and polymer thin films with thicknesses of several nanometers in polymer electrolyte fuel cells using MD simulations; further, we analyzed the correlation of the polymer structure with the vehicular ion diffusion [ 17 ], the structural ion diffusion [ 18 , 19 , 20 , 21 ], and the electroosmosis [ 22 ]. Based on these findings, the present study aimed to clarify the effect of nanoscale structural properties on the ion transport properties of the PEO-LiTFSI system and P(2EO-MO)-LiTFSI system.…”

Section: Introductionmentioning

confidence: 99%

Molecular Dynamics Study of Ion Transport in Polymer Electrolytes of All-Solid-State Li-Ion Batteries

2021

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Atomistic analysis of the ion transport in polymer electrolytes for all-solid-state Li-ion batteries was performed using molecular dynamics simulations to investigate the relationship between Li-ion transport and polymer morphology. Polyethylene oxide (PEO) and poly(diethylene oxide-alt-oxymethylene), P(2EO-MO), were used as the electrolyte materials, and the effects of salt concentrations and polymer types on the ion transport properties were explored. The size and number of LiTFSI clusters were found to increase with increasing salt concentrations, leading to a decrease in ion diffusivity at high salt concentrations. The Li-ion transport mechanisms were further analyzed by calculating the inter/intra-hopping rate and distance at various ion concentrations in PEO and P(2EO-MO) polymers. While the balance between the rate and distance of inter-hopping was comparable for both PEO and P(2EO-MO), the intra-hopping rate and distance were found to be higher in PEO than in P(2EO-MO), leading to a higher diffusivity in PEO. The results of this study provide insights into the correlation between the nanoscopic structures of ion solvation and the dynamics of Li-ion transport in polymer electrolytes.

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Effects of water nanochannel diameter on proton transport in proton‐exchange membranes

Cited by 25 publications

References 46 publications

Molecular dynamics of ionic polymer-metal composites

Molecular dynamics of ionic polymer-metal composites

Nafion Ionomer Dispersion in Mixtures of 1‐Propanol and Water Based on the Martini Coarse‐Grained Model

Molecular Dynamics Study of Ion Transport in Polymer Electrolytes of All-Solid-State Li-Ion Batteries

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