Preparation and Study of Sulfonated Co-Polynaphthoyleneimide Proton-Exchange Membrane for a H2/Air Fuel Cell

Zavorotnaya, Ulyana M.; Пономарев, И. И.; Volkova, Yulia A.; Модестов, А. Д.; Андреев, В. Н.; Privalov, A. F.; Vogel, Michael; Синицын, В. В.

doi:10.3390/ma13225297

Cited by 9 publications

(13 citation statements)

References 28 publications

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“…At higher hydration degrees, the environment of cations in membranes becomes similar to that for aqueous solutions of their salts, and the NMR chemical shifts approach these for aqueous solutions. The energy of interactions of large cesium cations with water molecules is insufficient to destroy the network of hydrogen bonds of water molecules, and the dependence of the 133 Cs chemical shift values on hydration degree is not pronounced [96,98]. This conclusion correlates well with dependences of 1 H chemical shifts on hydration degree [99,100].…”

Section: Hydration and Mobility Of Cations In Membranesmentioning

confidence: 51%

“…The correctness of these conclusions is proved by the fact that the diffusion coefficients for aqueous solutions of alkali metal chlorides, determined using both methods, are equal and close to the values found by NMR for membranes samples [ 107 ]. It should also be mentioned that the type of ion-exchange membrane significantly affects the ratio of the diffusion coefficients measured using NMR spectroscopy and conductivity [ 133 ].…”

Section: Ion Transfer In H + -Forms Of Membranementioning

confidence: 99%

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Ionic Mobility in Ion-Exchange Membranes

Стенина

Yaroslavtsev

2021

Membranes

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Membrane technologies are widely demanded in a number of modern industries. Ion-exchange membranes are one of the most widespread and demanded types of membranes. Their main task is the selective transfer of certain ions and prevention of transfer of other ions or molecules, and the most important characteristics are ionic conductivity and selectivity of transfer processes. Both parameters are determined by ionic and molecular mobility in membranes. To study this mobility, the main techniques used are nuclear magnetic resonance and impedance spectroscopy. In this comprehensive review, mechanisms of transfer processes in various ion-exchange membranes, including homogeneous, heterogeneous, and hybrid ones, are discussed. Correlations of structures of ion-exchange membranes and their hydration with ion transport mechanisms are also reviewed. The features of proton transfer, which plays a decisive role in the membrane used in fuel cells and electrolyzers, are highlighted. These devices largely determine development of hydrogen energy in the modern world. The features of ion transfer in heterogeneous and hybrid membranes with inorganic nanoparticles are also discussed.

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Section: Hydration and Mobility Of Cations In Membranesmentioning

confidence: 51%

Section: Ion Transfer In H + -Forms Of Membranementioning

confidence: 99%

Ionic Mobility in Ion-Exchange Membranes

Стенина

Yaroslavtsev

2021

Membranes

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“…22,39−42 We studied the temperature dependence of the self-diffusion coefficients for co-PNIS with the composition ODAS/MDAC = 70/30, which was wetted at 100% humidity. 43 It was found that D NMR has a similar temperature dependence in co-PNIS 70/30 and in Nafion with activation energies of 0.24 eV above and 0.32 eV below a crossover at T cr = 253 K. We expect that a variation of the ratio of the hydrophilic to hydrophobic polymer groups allows us to modify the diffusion pathways for water and, thus, the transport characteristics, as was observed for some other hydrocarbon-based membranes. 44−46 The goal of this work is to determine the dependence of the proton self-diffusion coefficients in co-PNIS polymers on the ratio of hydrophilic to hydrophobic groups at 100% humidity in a wide temperature range.…”

Section: Introductionmentioning

confidence: 67%

“…The chemical structure of co-polynaphthoylenimides based on MDAC, NTDA, and ODAS has been described in detail in our previous publications. 27,43,47,48 For the preparation of co-PNIS polymer films, the chemical components ODAS (0.5044 g, 0.0014 M), MDAC (0.1718 g, 0.0006 M), NTDA (0.5364 g, 0.002 M), benzoic acid catalyst (0.34 g, 0.0028 M), triethylamine solubilizer of ODAS (0.303 g, ∼0.003 M), and phenol or DMSO as solvents (10.0 g) were placed in a three-piece flask equipped with a stirrer and a capillary for introducing argon. 26,47 The reaction mass mixture was heated in an argon flow to 80 °C while stirring until all monomers were dissolved.…”

Section: Synthesis Of Co-pnis Membranesmentioning

confidence: 99%

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Diffusion in Sulfonated Co-Polynaphthoyleneimide Proton Exchange Membranes with Different Ratios of Hydrophylic to Hydrophobic Groups Studied Using SFG NMR

et al. 2022

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We use static field gradient (SFG) NMR to determine the self-diffusion coefficients of protons in fluorine-free sulfonated co-polynaphthoyleneimide (co-PNIS) proton exchange membranes with different ratios of hydrophilic to hydrophobic groups. The investigations were carried out in the temperature range from 193 to 355 K. Because there are protons not only in water but also in the polymer framework, 1H NMR diffusion studies of these membranes may suffer from cross-relaxation effects between the different types of protons. To overcome this problem, different methods for measuring proton diffusion coefficients are compared and a suitable strategy for analysis is proposed. It is found that the proton diffusion is practically isotropic and shows two activation regimes, separated by a crossover near 260 K. The activation energy above the crossover is 0.19 eV, which is close to that of Nafion 212. Below the crossover, all co-PNIS membranes studied have very similar diffusion coefficients and the activation energy amounts to 0.46 eV, which is higher than that of Nafion (0.36 eV). Increasing the ratio of hydrophilic to hydrophobic polymer groups leads to faster diffusion in the temperature range from 273 to 355 K. For the co-PNIS membranes with the highest ratio of hydrophilic to hydrophobic groups, the proton diffusivity is about 2.3 times higher than for the Nafion 212 membrane. Unlike for Nafion-type membranes, the diffusion does not depend on the length scale of the experiment, indicating that the morphology of co-PNIS membranes may differ from the channel-like structure of Nafion membranes.

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