Abstract
Ultrafiltration membranes, that respond to an external magnetic field and local temperature have been developed. Surface-initiated activator-generated electron transfer (AGET) atom transfer radical polymerization (ATRP) has been used to graft poly(N-isopropylacrylamide) (PNIPAm) from the surface of 300 kDa regenerated cellulose membranes. The polymerization initiator was selectively attached to the entire membrane surface, only the outer membrane surface or only the inner pore surface. A superparamagnetic nanoparticle was attached to the end of the polymer chain. The DI water flux as well as the flux and rejection of bovine serum albumin were investigated in the absence and presence of a 20 and 1000 Hz oscillating magnetic field. In an oscillating magnetic field, the tethered superparamagnetic nanoparticles can cause movement of the PNIPAm chains or induce heating. A 20 Hz magnetic field maximizes movement of the chains. A 1000 Hz magnetic field leads to greater induced heating. PNIPAm displays a lower critical solution temperature at 32 °C. Heating leads to collapse of the PNIPAm chains above their Lower Critical Solution Temperature (LCST). This work highlights the versatility of selectively grafting polymer chains containing a superparamagnetic nanoparticle from specific membrane locations. Depending on the frequency of the oscillating external magnetic field, membrane properties may be tuned.
Highlights
Ultrafiltration is an established pressure-driven membrane filtration process
By controlling the location of grafting, we can probe the effect of changes in the conforcontrolling the location of grafting, we canstimulus probe the of changes the conformation of the PNIPAm chains due to an external foreffect polymer chains in grafted from differmation of the PNIPAm chains due to anstimulus externalfor stimulus forchains polymer chains grafted of the PNIPAm chains due to an external polymer grafted different membrane surfaces
We showed that incorporation of a superparamagnetic nanoparticle at the end of a thermo-responsive polymer chain can enable remote performance modulation using an external magnetic field
Summary
Ultrafiltration is an established pressure-driven membrane filtration process These membranes are capable of retaining species in the size range 2000 to 500,000 Da. Rejected species include proteins, enzymes, DNA, virus particles, polymers and colloidal particles [1]. There has been growing interest in developing membranes whose performance can be modulated by environmental conditions. These stimuli-responsive membranes respond to an external stimulus [5,6,7]. One could include the responsive groups in the bulk membrane polymer or incorporate the responsive groups after membrane formation [8]. Numerous external stimuli have been investigated, such as pH, ionic strength, temperature, light and electric fields
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