Comparison of the Hydration and Diffusion of Protons in Perfluorosulfonic Acid Membranes with Molecular Dynamics Simulations

Cui, Shaogang; Liu, Junwu; Selvan, Myvizhi Esai; Paddison, Stephen J.; Keffer, David J.; Edwards, Brian J.

doi:10.1021/jp8039803

Cited by 120 publications

(163 citation statements)

References 111 publications

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“…Since we have attempted to limit the entanglement of the polymer chains when generating the systems, and since the least entangled systems by Knox and Voth also seem to be the ones closest to experiment, one might speculate that this is one key feature leading to the observed features in the scattering experiments, as expressed in the so-called ionomer peak. In contrast to some earlier work [54,69], we do not observe significant differences between Nafion and Hyflon. Since both the 'cylindrical' model and the 'random' model proposed here as well as most of Voth's model systems reproduce the experimental scattering data satisfactorily, we must conclude that the scattering data alone are not sufficient to elucidate the structure of systems as complex as proton exchange membranes in water, hence the ongoing debate over their morphology.…”

Section: Discussioncontrasting

confidence: 99%

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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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Section: Discussioncontrasting

confidence: 99%

“…4). This is at variance with the work of Cui et al [68,69] who observed a less dispersed water distribution in Nafion as compared to Hyflon.…”

Section: Cluster Analysiscontrasting

confidence: 83%

Molecular Simulations of Hydrated Proton Exchange Membranes: the Structure

Marchand

Bopp

Spohr

2013

Zeitschrift Für Naturforschung A

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“…The classical molecule dynamics (MD) and ab initio molecular dynamics (AIMD) methods were used to determine proton mobility as a function of hydration conditions and sulfonated function rings [14][15]. Studies on SSC PFSA membrane fragments show that the formation of hydrogen bonds between water molecules is highly dependent on acid ring connectivity.…”

Section: Introductionmentioning

confidence: 99%

<i>Ab Initio</i> Study of Proton Transfer and Hydration in Phosphorylated Nata de Coco

2017

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This research aims to calculate energetics parameters, hydrogen bonding, characteristics local hydration, and proton transfer in phosphorylated nata de coco (NDCF) membrane using ab initio method. The minimum energy structure of NDCF membranes and the addition of n water molecules (n = 1-10) Calculation of the rotational energy at the center of C-O indicates that the pyranose ring structure, with a maximum barrier energies of~12.5 J/mol, is much more flexible than the aromatic backbones of sulfonated poly(phenylene) sulfone (sPSO2) and the polytetrafluoroethylene (PTFE) backbones in perfluorosulfonic acid ionomers (PFSA). These energy calculations provide the basis that the flexibility of the pyranose ring and the hydrogen bonding between water molecules and phosphonate groups influence the transfer of protons in the membrane of NDCF. Keywords: proton transfer; ab initio; nata de coco ABSTRAK Penelitian ini bertujuan untuk menghitung parameter energetika, ikatan hidrogen, karakteristik hidrasi lokal, dan transfer proton pada membran nata de coco terfosfosfatasi menggunakan metode ab initio. Struktur energi minimum untuk nata de coco terfosfatasi dan penambahan n molekul air (n = 1-10) yang ditentukan dengan metode B3LYP/6-311G(d) menunjukkan bahwa untuk disosiasi proton minimal dibutuhkan empat molekul air. Proton yang terdisosiasi distabilkan dengan terbentuknya ion-ion hidronium, Zundel dan Eigen. Perhitungan energi interaksi dengan n molekul air menunjukkan perubahan energi (∆E), dan perubahan entalpi (∆H) yang semakin negatif. Hal ini

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“…[5] Among these membranes, Nafion is studied extensively by experiments [2,6] and computational methods. [7][8][9][10][11][12] However, the conductivity of Nafion membrane is strongly dependent on its hydration. [13][14][15][16][17] The operating temperature of fuel cells using Nafion is limited to the boiling point of water, that is, 100 C, and at this temperature, there is low tolerance of the electro-catalyst like platinum against CO poisoning.…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics simulations of triflic acid and triflate ion/water mixtures: A proton conducting electrolytic component in fuel cells

Sunda

Venkatnathan

2011

J Comput Chem

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Triflic acid is a functional group of perflourosulfonated polymer electrolyte membranes where the sulfonate group is responsible for proton conduction. However, even at extremely low hydration, triflic acid exists as a triflate ion. In this work, we have developed a force-field for triflic acid and triflate ion by deriving force-field parameters using ab initio calculations and incorporated these parameters with the Optimized Potentials for Liquid Simulations - All Atom (OPLS-AA) force-field. We have employed classical molecular dynamics (MD) simulations with the developed force field to characterize structural and dynamical properties of triflic acid (270-450 K) and triflate ion/water mixtures (300 K). The radial distribution functions (RDFs) show the hydrophobic nature of CF(3) group and presence of strong hydrogen bonding in triflic acid and temperature has an insignificant effect. Results from our MD simulations show that the diffusion of triflic acid increases with temperature. The RDFs from triflate ion/water mixtures shows that increasing hydration causes water molecules to orient around the SO(3)(-) group of triflate ions, solvate the hydronium ions, and other water molecules. The diffusion of triflate ions, hydronium ion, and water molecules shows an increase with hydration. At λ = 1, the diffusion of triflate ion is 30 times lower than the diffusion of triflic acid due to the formation of stable triflate ion-hydronium ion complex. With increasing hydration, water molecules break the stability of triflate ion-hydronium ion complex leading to enhanced diffusion. The RDFs and diffusion coefficients of triflate ions, hydronium ions and water molecules resemble qualitatively the previous findings using per-fluorosulfonated membranes.

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Comparison of the Hydration and Diffusion of Protons in Perfluorosulfonic Acid Membranes with Molecular Dynamics Simulations

Cited by 120 publications

References 111 publications

Molecular Simulations of Hydrated Proton Exchange Membranes: the Structure

Molecular Simulations of Hydrated Proton Exchange Membranes: the Structure

<i>Ab Initio</i> Study of Proton Transfer and Hydration in Phosphorylated Nata de Coco

Molecular dynamics simulations of triflic acid and triflate ion/water mixtures: A proton conducting electrolytic component in fuel cells

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