Abstract
We study the permeability and selectivity ('permselectivity') of model membranes made of polydisperse polymer networks for molecular penetrant transport, using coarse-grained, implicit-solvent computer simulations. In our work, permeability P is determined on the linear-response level using the solution-diffusion model, P = KDin, i.e., by calculating the equilibrium penetrant partition ratio K and penetrant diffusivity Din inside the membrane. We vary two key parameters, namely the network-network interaction, which controls the degree of swelling and collapse of the network, and the network-penetrant interaction, which tunes the selective penetrant uptake and microscopic energy landscape for diffusive transport. We find that the partitioning K covers four orders of magnitude and is a non-monotonic function of the parameters, well interpreted by a second-order virial expansion of the free energy of transferring one penetrant from a reservoir into the membrane. Moreover, we find that the penetrant diffusivity Din in the polydisperse networks, in contrast to highly ordered membrane structures, exhibits relatively simple exponential decays. We propose a semi-empirical scaling law for the penetrant diffusion that describes the simulation data for a wide range of densities and interaction parameters. The resulting permeability P turns out to follow the qualitative behavior (including maximization and minimization) of partitioning. However, partitioning and diffusion are typically anti-correlated, yielding large quantitative cancellations, controlled and fine-tuned by the network density and interactions, as rationalized by our scaling laws. We finally demonstrate that even small changes of network-penetrant interactions, e.g., by half a kBT, modify the permselectivity by almost one order of magnitude.
Highlights
Other important examples of polymer-network-based membranes can be found in functional soft matter composed of synthetic hydrogels, such as cross-linked poly(N-isopropylacrylamide) (PNIPAM).[19]
We focus on two important control parameters: the polymer network density fn, tuned by internal interactions, and the interaction between the network monomers and the penetrants
Upon changing the network–penetrant interaction, while using intermediate solvent quality, we note that the larger the attraction enp, the more packed is the network
Summary
Other important examples of polymer-network-based membranes can be found in functional soft matter composed of synthetic hydrogels, such as cross-linked poly(N-isopropylacrylamide) (PNIPAM).[19] Due to their thermoresponsiveness and relatively sharp volume transition, they are widely used as representative and promising components in emerging material technologies for stimuli-responsive carrier particles, actuators, sensors, or responsive nanoreactors.[20,21,22,23,24,25,26,27,28,29,30,31,32,33] In the latter, for instance, the hydrogel embeds nano-sized enzymes or metal nanoparticles catalyzing chemical reactions, which are controlled. Paper by responsive membrane permeability.[34,35,36] In general, responsive polymeric matrices can be expected to control the permeation of solutes (penetrants) in a selective manner, modulated by external stimuli such as temperature, pH, and salinity. The tunable selectivity of permeability (‘permselectivity’)[4] bears enormous potential for the development of ‘intelligent’, programmable and adaptive membranes for diverse applications ranging from gas separation,[37,38,39,40,41,42,43] water purification, and filtration[44,45,46,47,48,49,50] to dialysis and drug delivery.[51,52]
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