Abstract
In recent work, Aqueous Phase Separation (APS) based on pH change induced polyelectrolyte complexation has shown great potential for the preparation of sustainable polymeric membranes with tunable structures. Unfortunately, thus far this has only been possible with a single polyelectrolyte combination. In this work, we demonstrate that this APS approach extends beyond a single system by preparing sustainable membranes from polyelectrolyte complexes (PECs) of the weak polyanion poly(acrylic acid) (PAA) and the strong polycation poly(diallyldimethylammonium chloride) (PDADMAC). PE solutions are mixed in an acidic medium where PAA is uncharged, and then this mixture is cast and immersed in a coagulation bath at a pH where PAA becomes charged and able to form a PEC with the oppositely charged PDADMAC. Since this process includes both phase separation and PE complexation, it is expected that membrane structure and performance is influenced by a combination of many factors. Casting solution pH, PAA molecular weight, and coagulation bath pH all directly affect the phase separation behavior of PAA/PDADMAC complexes in ways similar to conventional nonsolvent induced phase separation (NIPS). In addition, coagulation bath salinity and PE mixing ratio influence the complexation behavior. Through tuning of all these parameters it is possible to create a wide variety of membrane structures, ranging from nodular symmetrically porous membranes, to asymmetric membranes with cellular pores and in some cases dense top layers. The nodular membranes show good performance as microfiltration membranes with excellent oil retention (>95% for 3–4 µm droplets) and good water permeances. However for the cellular membranes, filtration led to collapse of the porous structure, emphasizing the importance of PE selection for membrane applications.
Highlights
Polymeric membranes are mostly produced by phase separation techniques
Membranes were obtained from aqueous phase se paration induced by pH triggered polyelectrolyte complexation
An immediate result of this current work is that membrane formation with pH induced polyelec trolytes (PEs) complexation is shown to be widely applicable, rather than just being the feature of a single polyelectrolyte couple
Summary
Polymeric membranes are mostly produced by phase separation techniques. Nonsolvent induced phase separation (NIPS) is the pre ferred approach due its versatility and simplicity [1]. For NIPS, a polymer is dissolved in an organic solvent and precipitated in the form of a membrane when the polymer solution is immersed in a nonsolvent bath (commonly water). The nonsolvent must be miscible with the solvent so that solvent can diffuse out and nonsolvent can diffuse into the polymer solution to trigger precipitation of the polymer upon im mersion. The interactions of polymer, solvent, and nonsolvent together with the kinetics of phase separation are the main factors that affect membrane structure and membrane performance. NIPS is very well-established since its discovery in the early 1960s and there exist many factors that affect the process. The toxicity of com monly used solvents for NIPS such as N-methyl-2-pyrrolidone (NMP)
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