Swelling and permeability of Nafion ®117 in water–methanol solutions: An experimental and modelling investigation

► We study swelling and diffusion behaviour of Nafion117 in water-methanol solutions. ► We develop a new model for water-methanol permeation through Nafion membrane. ► This model takes into account the adjacent diffusion boundary layers (DBLs). ► DBLs contribution is important at low stirring rates...

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Bibliographic Details
Published in:Journal of membrane science 2011-07, Vol.377 (1), p.54-64
Main Authors: Chaabane, L., Dammak, L., Grande, D., Larchet, C., Huguet, P., Nikonenko, S.V., Nikonenko, V.V.
Format: Article
Language:English
Subjects:
artificial membranes
Chemical Sciences
Diffusion boundary layer
diffusivity
electrodes
electrolytes
equations
hydrochloric acid
ion exchange
Ion-exchange membrane
Mathematical modelling
mathematical models
membrane permeability
methanol
Methanol uptake
mixers
porosity
spectroscopy
Water–methanol mutual diffusion
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Summary:► We study swelling and diffusion behaviour of Nafion117 in water-methanol solutions. ► We develop a new model for water-methanol permeation through Nafion membrane. ► This model takes into account the adjacent diffusion boundary layers (DBLs). ► DBLs contribution is important at low stirring rates and negligible at higher rates. ► Methanol could occupy regions close to hydrophobic chains not available for water. The swelling and diffusion behaviour of a Nafion ®117 ion-exchange membrane was investigated in mixed water–methanol solutions. The membrane porosity was found as a function of the methanol content in solution. The water and methanol uptake was determined by Raman spectrometry. The permeation experiments were realized in conditions where a membrane initially separated a water–methanol electrolyte solution from a solution prepared with pure water, both solutions containing either 0.1 M HCl or 0.5 M HCl. Different rotation speeds of stirrer rods were applied in the range of 70–700 rpm. A mathematical model for water–methanol permeation through a membrane taking into account the transfer through adjacent diffusion boundary layers (DBLs) and the dependence of the methanol diffusion coefficient on the methanol concentration was developed. The DBL thickness, δ, and the methanol permeability, P*, were determined by numerical fitting of experimental data. It was found that the rotating stirrers used in the cell were almost as efficient as rotating electrodes or membranes: we have found that δ ≈ 1.2 δ Levich, where δ Levich was calculated by the well-known Levich equation for rotating disc electrodes. However, the contribution of diffusion resistance of DBL into the overall resistance of the three-layer system was not negligible, even at high rotation speeds, due to high methanol permeation through Nafion ®117. When taking into account the DBLs, the “true” methanol permeability of Nafion ®117 in the presence of 0.5 M HCl in the upstream and downstream compartments (at 25 °C) was equal to 0.44 × 10 −5 cm 2 s −1. If the contribution of DBLs was not considered, the apparent methanol permeability at rotation speed of 70 rpm ( δ ≈ 76 μm) was equal to 0.35 × 10 −5 cm 2 s −1. Even at 650 rpm ( δ ≈ 25 μm), the apparent methanol permeability, (0.41 × 10 −5 cm 2 s −1) was still lower than its “true” value. An approximate equation relating the apparent (efficient) non-electrolyte permeability with the “true” membrane permeability and the diffusion layer thickness was
ISSN:0376-7388
1873-3123
DOI:10.1016/j.memsci.2011.03.037