The
origin of property enhancement of nanocomposite ion exchange
membranes (IEMs) is far from being fully understood. By combining
experimental work and computational modeling analysis, we could determine
the influence of nanomaterials on the ion transport properties of
nanocomposite cation exchange membranes (CEMs). We synthesized and
characterized a series of nanocomposite CEMs by using SPPO as polymer
materials and silica nanoparticles (NPs) (unsulfonated or sulfonated)
as nanomaterials. We found that with the increase of NP loading, measured
CEM permselectivity and swelling degree first increased and then decreased.
We also found the ion exchange capacity (IEC) and ionic resistance
of nanocomposite CEMs tend to be the same, regardless what type of
NPs are incorporated into the membrane. Modeling analysis suggests
that the change of membrane properties is related to the change in
membrane microstructure. With the addition of silica NPs, membrane
porosity (volume fraction of intergel phase) increases so that membranes
can absorb more water. Also, volume fraction of sulfonated polymer
segments increases, which can allow membranes to retain more counterions,
causing membrane IEC to increase. By calculating the effective ion
diffusion coefficients and membrane tortuosity factors of all the
silica-NP-based CEMs synthesized in this study, along with nanocomposite
CEMs from previous studies, we conclude that membrane ion transport
efficiency tends to increase with the incorporation of nanomaterials.
In addition, this paper presents a simulation model, which explains
how the membrane property changes upon nanomaterial aggregation; the
simulation results are in good agreement with the experimental data.
Simulation results indicate that membrane properties are related to
nanomaterial number concentration in the membrane matrices; thus,
a plateau is reached for membrane ion diffusion coefficients due to
the severe influence of aggregation on the increase of nanomaterial
real number concentration. The results of this study can provide insight
into membrane structure–property relation and contribute to
the value of future designs of new nanocomposite IEMs.