posted on 2023-04-06, 19:39authored byRyan M. DuChanois, Lauren Mazurowski, Hanqing Fan, Rafael Verduzco, Oded Nir, Menachem Elimelech
Separation of specific ions from
water could enable recovery and
reuse of essential metals and nutrients, but established membrane
technologies lack the high-precision selectivity needed to facilitate
a circular resource economy. In this work, we investigate whether
the cation/cation selectivity of a composite cation-exchange membrane
(CEM), or a thin polymer selective layer on top of a CEM, may be limited
by the mass transfer resistance of the underlying CEM. In our analysis,
we utilize a layer-by-layer technique to modify CEMs with a thin polymer
selective layer (∼50 nm) that has previously shown high selectivity
toward copper over similarly sized metals. While these composite membranes
have a CuCl2/MgCl2 selectivity up to 33 times
larger than unmodified CEMs in diffusion dialysis, our estimates suggest
that eliminating resistance from the underlying CEM could further
increase selectivity twofold. In contrast, the CEM base layer has
a smaller effect on the selectivity of these composite membranes in
electrodialysis, although these effects could become more pronounced
for ultrathin or highly conductive selective layers. Our results highlight
that base layer resistance prevents selectivity factors from being
comparable across diffusion dialysis and electrodialysis, and CEMs
with low resistance are necessary for providing highly precise separations
with composite CEMs.