Abstract
In this paper, we simulate the changes in the structure and transport properties of an anion-exchange membrane (CJMA-7, Hefei Chemjoy Polymer Materials Co. Ltd., China) caused by its modification with a perfluorosulfonated ionomer (PFSI). The modification was made in several stages and included keeping the membrane at a low temperature, applying a PFSI solution on its surface, and, subsequently, drying it at an elevated temperature. We applied the known microheterogeneous model with some new amendments to simulate each stage of the membrane modification. It has been shown that the PFSI film formed on the membrane-substrate does not affect significantly its properties due to the small thickness of the film (≈4 µm) and similar properties of the film and substrate. The main effect is caused by the fact that PFSI material “clogs” the macropores of the CJMA-7 membrane, thereby, blocking the transport of coions through the membrane. In this case, the membrane microporous gel phase, which exhibits a high selectivity to counterions, remains the primary pathway for both counterions and coions. Due to the above modification of the CJMA-7 membrane, the coion (Na+) transport number in the membrane equilibrated with 1 M NaCl solution decreased from 0.11 to 0.03. Thus, the modified membrane became comparable in its transport characteristics with more expensive IEMs available on the market.
Highlights
The selectivity of ion-exchange membranes (IEM) in relation to counterion transport is the main functional property of this type of membranes
The CJMA-7 membrane was modified in several stages: (1) a sample of a pristine CJMA-7 membrane (CJMA-7pr) was kept in a fridge for a year at a temperature of 4–6 ◦C in a 0.1 eq L−1 NaCl solution (CJMA-7fr); after that, the obtained membrane was divided in two samples; (2) one of the samples was poured with a 7% perfluorosulfonated ionomer (PFSI) solution and dried at room temperature for h; (3) the obtained membrane was divided into two more samples; both samples were dried for an extra 1 h: the first one at ◦C (CJMA-7fr-mod25) and the second one at 50 ◦C (CJMA-7fr-mod50) in a drying oven
The microheterogeneous model with some new amendments is applied to simulate the changes in membrane structure and related transport properties due to different modifications of an anion-exchange CJMA-7 membrane
Summary
The selectivity of ion-exchange membranes (IEM) in relation to counterion transport is the main functional property of this type of membranes. This property determines the possibility of desalination and concentration of electrolyte solutions by the electrodialysis method [1,2,3]. Models of the first type do not allow one to determine an explicit relationship between the parameters of the membrane structure and transport coefficients This relationship can be established, when considering the membrane as a multiphase microheterogeneous system (effective-medium approach) [55]. We take into account that the intergel spaces are not completely filled with the aqueous solution, but partially with the PFSI material
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