Isotopic and Ion-Exchange Kinetics in the Nafion-117 Membrane

Suresh, G.; Scindia, Y.M.; Pandey, Ashok K.; Goswami, A.

doi:10.1021/jp037058v

Cited by 44 publications

(78 citation statements)

References 21 publications

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“…[35][36][37][38][39][40] Finally, an average coverage along the channel can be obtained by integration of the local coverage along the length of the channel, 0 < ξ < 1:…”

Section: Modelmentioning

confidence: 99%

“…The diffusion coefficient of water vapor through the GDL was used for gas (i.e., water vapor+air+contaminant) diffusion through GDL, and the diffusion coefficients of methanol, ammonium and Na + in Nafion membrane were used to represent the diffusion of DEGEE, 2,6-DAT, and Na + in the ionomer and membrane, respectively, because of the lack of data. [35][36][37][38][39][40][49][50][51] Scaling from ex situ experiments to in situ predictions.-Our goal for the model is to predict voltage losses using ex situ measurements. For the Pt coverage, our data indicates that equilibrium is obtained (Figure 10 quickly in the liquid phase ex situ measurements performed with thinfilm electrodes (TFEs).…”

Section: Comparison To Experimental Datamentioning

confidence: 99%

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An Isothermal Model for Predicting Performance Loss in PEMFCs from Balance of Plant Leachates

Cho

Zee

2014

J. Electrochem. Soc.

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A model is presented for the contamination of a proton exchange membrane fuel cell (PEMFC), including adsorption onto the Pt catalyst, absorption into the membrane, and ion exchange with ionomeric components. Model predictions for three sources of voltage loss account for the two-dimensional, time-dependent contamination along the channel and into the membrane. The model is developed by considering the well-known concepts of Langmuir adsorption, partition coefficients, plug flow reactors (PFRs), and dimensionless analysis. The phenomena are shown to be controlled by three important dimensionless groups: a Damköhler number for the contamination reaction rate, a capacity ratio, and a coverage ratio for each contamination mechanism. These groups show how to scale ex situ equilibrium data for in situ predictions. The model predictions are shown to be reasonable when compared to in situ experiment data once ex situ data are used to provide reaction and equilibrium parameters. The predictions enable estimation of tolerance limits for leachates according to each mechanism. For typical parameters, the predicted voltage loss in the electrode ionomer by an ion-exchange mechanism shows slower reaction rates but greater performance losses than other mechanisms. Analysis of the potential for commercialization of proton exchange membrane fuel cells (PEMFCs) shows that the cost of balance of plant (BOP) materials can be as much as 30% of the system cost.1 One opportunity to decrease these costs is to use off-the-shelf materials rather than custom-made materials, if leachates from less expensive materials would not affect performance and life-time.2 This loss in performance is related to the contamination of the membrane 3 as well as the electrodes. Many previous studies for contamination [3][4][5][6][7][8][9][10][11][12][13] in PEMFCs have shown the sensitivity of performance to low levels of contamination. For example, cation leachates from gaskets or seals, from NH 3 in the fuel, or from catalyst metals 3-9 are well known contaminants of the membrane through an ion-exchange mechanism. Catalyst contamination by CO through an adsorption mechanism from feed gas contaminants is so well-known that those studies are too numerous to list here. Examples are also known for SO 2 , 10,11 for H 2 S, 12 and even for details of the reverse water-gas shift reaction of CO 2 . 13The fundamental mechanism of contamination from organic contaminants such as aniline, ε-caprolactam, and diaminotoluene (DAT), [14][15][16][17][18] which have been identified as possible system contaminants, have been studied only briefly and recently, and it has been shown that their impact on PEMFC performance depends on their functional groups. For example, the ion-exchange reaction of the amine group in aniline with the Nafion membrane/ionomer causes a decrease in the number of available proton sites, thereby hindering the transport of protons and increasing ohmic losses. Aniline is also adsorbed on the carbonsupported platinum catalyst through interactions betw...

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“…[35][36][37][38][39][40] Finally, an average coverage along the channel can be obtained by integration of the local coverage along the length of the channel, 0 < ξ < 1:…”

Section: Modelmentioning

confidence: 99%

Section: Comparison To Experimental Datamentioning

confidence: 99%

An Isothermal Model for Predicting Performance Loss in PEMFCs from Balance of Plant Leachates

Cho

Zee

2014

J. Electrochem. Soc.

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Section: Least-squares Modelingmentioning

confidence: 99%

“…An important advance in the study was learning that the elements in C could be predicted from the mass transport equation for diffusion in a cylindrical pore in the long time limit [57][58][59][60]. This diffusion equation is known to describe the transport of water and ions within Nafion membrane [58][59][60]. The equation has the form where N is the number of species in the film undergoing transport at time t, N max is the maximum N attained after long measurement periods, and t is a time constant given by the ratio of the pore length L (usually taken as the membrane thickness), and the diffusion coefficient for analyte in the pore D (t ¼ L 2 /D) [57][58][59][60].…”

Section: Least-squares Modelingmentioning

confidence: 99%

Vibrational Spectroscopy for the Characterization of PEM Fuel Cell Membrane Materials

Korzeniewski

2010

Fuel Cell Science

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“…The spectra were examined by applying a least squares approach [7,8]. A diffusion equation that describes molecular transport within a cylindrical pore [9][10][11] was used to predict the time dependent uptake of water into the membrane [1,3]. The analysis revealed bands for vibrational modes for the more hydrophobic polymer functional groups (-CF 2 and -C-O-C-) changed as predicted by the diffusion equation, whereas the response of the prominent band for the asymmetric S-O stretching mode of the hydrophilic -SO 3 -group (near 1064 cm -1 (Fig.…”

Section: Abstract Progress Report and Future Directionsmentioning

confidence: 99%

Strategies for Probing Nanometer-Scale Electrocatalysts: From Single Particles to Catalyst-Membrane Architectures

Korzeniewski

2014

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Objectives Abstract, Progress Report and Future Directions A. Fuel Cell Membrane and Catalyst-Membrane Architectures Probed by VibrationalSpectroscopy: Infrared and Raman spectroscopy were investigated as probes of structures within proton conductive materials that limit or enhance performance in polymer electrolyte fuel cells. The following were primary accomplishments: (a) least squares modeling in conjunction with infrared spectroscopy was demonstrated as a useful approach to detect differences in the response of hydrophilic and more hydrophobic functional groups in ionomer materials undergoing changes in hydration state [1]; (b) strategies developed during the project through studies of model Nafion membranes [2][3][4] were adapted to investigate new bis(perfluoroalkylsulfonyl) imide [5] and fluoroalkyl phosphonate [6] ionomer materials; (c) the capabilities of Raman spectroscopy were explored for its potential to enable depth profiling of practical fuel cell membrane and in situ studies of fuel cell catalyst-membrane architectures.

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Isotopic and Ion-Exchange Kinetics in the Nafion-117 Membrane

Cited by 44 publications

References 21 publications

An Isothermal Model for Predicting Performance Loss in PEMFCs from Balance of Plant Leachates

An Isothermal Model for Predicting Performance Loss in PEMFCs from Balance of Plant Leachates

Vibrational Spectroscopy for the Characterization of PEM Fuel Cell Membrane Materials

Strategies for Probing Nanometer-Scale Electrocatalysts: From Single Particles to Catalyst-Membrane Architectures

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