Mesoscale simulation of morphology in hydrated perfluorosulfonic acid membranes

Wescott, James T.; Qi, Yue; Subramanian, Lalitha; Capehart, T. W.

doi:10.1063/1.2177649

Cited by 174 publications

(166 citation statements)

References 59 publications

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“…Nevertheless, Wescott et al 100 found that, in common with the DPD simulations of Yamamoto and Hyodo 94 there was a reasonable agreement between the absolute cluster sizes predicted by SCMFT and those observed in scattering experiments. Significantly, they found a linear increase in characteristic size scale of the morphologies with increasing water content, which provides a counterexample to earlier suppositions that this must necessarily imply a lamellar morphology.…”

Section: Mesoscale Modelsmentioning

confidence: 62%

Modelling of morphology and proton transport in PFSA membranes

Elliott

Paddison

2007

Phys. Chem. Chem. Phys.

227

255

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Computational modelling studies of the structure of perfluorosulfonic acid (PFSA) ionomer membranes consistently exhibit a nanoscopic phase-separated morphology in which the ionic side chains and aqueous counterions segregate from the fluorocarbon backbone to form clusters or channels. Although these investigations do not unambiguously predict the size or shape of the clusters, and whether or not the channels percolate the matrix or if the connections between them are more transient, the sequence of co-monomers along the main chain appears strongly to influence the domain size of the ionic regions, with more blocky sequences giving rise to larger domain sizes. The fundamental insight that substantial rearrangement of the sulfonic acid terminated side chains and fluorocarbon backbone takes place during swelling or shrinkage is borne out by both molecular and mesoscale simulations of model PFSA polymers, along with ab initio electronic structure calculations of minimally hydrated oligomeric fragments. Molecularlevel modelling of proton transport in PFSA membranes attests to the complexity of the underlying mechanisms and the need to examine the chemical and physical processes at several distinct time and length scales. These investigations have revealed that the conformation of the fluorocarbon backbone, flexibility of the sidechains, and degree of aggregation and association of the sulfonic acid groups under minimally hydrated conditions collectively control the dissociation of the protons and the formation of Zundel and Eigen cations. The former appear to be the dominant charge carriers when the limiting water content allows only for the formation of a contact ion pair with the tethered sulfonate anion. As the water content increases, solventseparated Eigen ions begin to appear, indicating that the dominant mechanism for diffusion of protons occurs over a region approximately 4 Å away from the sulfonate groups. Finally, both the vehicular and Grotthuss shuttling mechanisms contribute to the mobility of the protons but, surprisingly, they are not always correlated, resulting in a lower overall diffusion coefficient. In summary, as the preceding observations indicate, the state of computational modelling of PFSA membranes has progressed sufficiently over the last decade to enable its use as a powerful predictive tool with which to guide the process of designing novel membrane materials for fuel cell applications.

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Section: Mesoscale Modelsmentioning

confidence: 62%

Modelling of morphology and proton transport in PFSA membranes

Elliott

Paddison

2007

Phys. Chem. Chem. Phys.

227

255

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“…The commercial force field COM-PASS was used, and their potential parameters were listed in the literature. 19,43,44 All of the molecular simulations were carried out using a Hewlett-Packard workstation and the Material Studio software package (Accelrys Inc., CA, U.S.A.).…”

Section: Simulation Proceduresmentioning

confidence: 99%

“…For PEMs, extensive studies have been carried out to investigate their peculiar structures and proton transport behavior. 19,20 Paddison used ab initio strategy to study proton dissociation of the sulfonic acid group in triflic acid and p-toluene sulfonic acid, simulating Nafion and PEEKK models, respectively. 21 Later, he and Elliott performed ab initio calculations to investigate proton dissociation of the short side chain of a perfluorosulfonic acid membrane such as Nafion and the resulting proton transfer with solvent molecules.…”

Section: Introductionmentioning

confidence: 99%

Phase Separation and Water Channel Formation in Sulfonated Block Copolyimide

et al. 2010

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Vous avez des questions? Nous pouvons vous aider. Pour communiquer directement avec un auteur, consultez la première page de la revue dans laquelle son article a été publié afin de trouver ses coordonnées. Si vous n'arrivez pas à les repérer, communiquez avec nous à PublicationsArchive-ArchivesPublications@nrc-cnrc.gc.ca. Questions? Contact the NRC Publications Archive team atPublicationsArchive-ArchivesPublications@nrc-cnrc.gc.ca. If you wish to email the authors directly, please see the first page of the publication for their contact information. NRC Publications Archive Archives des publications du CNRCThis publication could be one of several versions: author's original, accepted manuscript or the publisher's version. / La version de cette publication peut être l'une des suivantes : la version prépublication de l'auteur, la version acceptée du manuscrit ou la version de l'éditeur. NRC Publications Record / Notice d'Archives des publications de CNRC:http://nparc.cisti-icist.nrc-cnrc.gc.ca/eng/view/object/?id=8d7de2db-497c-4114-a4b2-c67045bf8c68 http://nparc.cisti-icist.nrc-cnrc.gc.ca/fra/voir/objet/?id=8d7de2db-497c-4114-a4b2-c67045bf8c68 We compared experimental and simulated data to investigate the phase separation and water channel formation of proton exchange membranes (PEMs) for fuel cell. Sulfonated block copolyimides (SPIs) were adopted as model polymers for experiments and simulations, and Nafion was used as a reference. Nafion and SPIs were observed to have different microscopic structures such as constituent atoms, backbone rigidity, and the locations of sulfonic acid groups, all of which significantly affect phenomenological properties at the macroscopic level such as density, water uptake, and proton conductivity. In particular, SPIs show much weaker microphase separation than Nafion, mainly due to the lower mobility of sulfonic acid groups and the existence of acceptable sites for hydrogen bonding even in hydrophobic segments, which impedes water channel formation for proton transport. As a result, the phase separation behavior and the resulting water channel formation are the major factors affecting macroscopic properties of PEMs such as water uptake and proton transport. Phase Separation and Water Channel Formation in Sulfonated Block

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“…Wescott et al [45], for example, performed mesoscale simulations of hydrated Nafion using a self-consistent mean field theory approach and a coarse-grained model, deriving the interaction parameters from classical MD. In this study, four systems (with different water contents) with an initially homogeneous distribution of the components were simulated at room temperature.…”

Section: Introduction and Reviewmentioning

confidence: 99%

Molecular Simulations of Hydrated Proton Exchange Membranes: the Structure

Marchand

Bopp

Spohr

2013

Zeitschrift Für Naturforschung A

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The structure of two hydrated proton exchange membranes for fuel cells (PEMFC), Nafion ® (Dupont) and Hyflon ® (Solvay), is studied by all-atom molecular dynamics (MD) computer simulations. Since the characteristic times of these systems are long compared to the times for which they can be simulated, several different, but equivalent, initial configurations with a large degree of randomness are generated for different water contents and then equilibrated and simulated in parallel. A more constrained structure, analog to the newest model proposed in the literature based on scattering experiments, is investigated in the same way. One might speculate that a limited degree of entanglement of the polymer chains is a key feature of the structures showing the best agreement with experiment. Nevertheless, the overall conclusion remains that the scattering experiments cannot distinguish between the several, in our view equally plausible, structural models.We thus find that the characteristic features of experimental scattering curves are, after equilibration, fairly well reproduced by all systems prepared with our method. We thus study in more detail some structural details. We attempt to characterize the spatial and size distribution of the water rich domains, which is where the proton diffusion mostly takes place, using several clustering algorithms.

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Mesoscale simulation of morphology in hydrated perfluorosulfonic acid membranes

Cited by 174 publications

References 59 publications

Modelling of morphology and proton transport in PFSA membranes

Modelling of morphology and proton transport in PFSA membranes

Phase Separation and Water Channel Formation in Sulfonated Block Copolyimide

Molecular Simulations of Hydrated Proton Exchange Membranes: the Structure

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