Abstract
With the aim of exploring new materials and properties, we report the synthesis of a thermoplastic chain extended polyurethane membrane, with superior strength and toughness, obtained by incorporating two different concentrations of reactive cellulose nanocrystals (CNC) for potential use in kidney dialysis. Membrane nanocomposites were prepared by the phase inversion method and their structure and properties were determined. These materials were prepared from a polyurethane (PU) yielded from poly(1,4 butylene adipate) as a soft segment diol, isophorone diisocyanate (IPDI) and hexamethylenediamine (HMDA) as isocyanate and chain extender, respectively (hard segment), filled with 1 or 2% w/w CNC. Membrane preparation was made by the phase inversion method using N,N-dimethylformamide as solvent and water as nonsolvent, and subjected to dead-end microfiltration. Membranes were evaluated by their pure water flux, water content, hydraulic resistance and protein rejection. Polymers and nanocomposites were characterized by scanning electronic and optical microscopy, differential scanning calorimetry, infrared spectroscopy, strain stress testing and 13C solid state nuclear magnetic resonance. The most remarkable effects observed by the addition of CNCs are (i) a substantial increment in Young’s modulus to twenty-two times compared with the neat PU and (ii) a marked increase in pure water flux up to sixty times, for sample containing 1% (w/w) of CNC. We found that nanofiller has a strong affinity to soft segment diol, which crystallizes in the presence of CNCs, developing both superior mechanical and pure water flow properties, compared to neat PU. The presence of nanofiller also modifies PU intermolecular interactions and consequently the nature of membrane pores.
Highlights
Polyurethane (PU) has been widely applied in many industries as a versatile material due to its relatively easy manufacture, low cost, the accessible source of their raw materials and because they are typically used as glues, fibers, coatings and hoses among other applications
It is observed that the peak shifts upfield from 64.6 (PU) to 64.4 and 64.3 ppm for NC 2 and NC 1, respectively. These results indicate that the soft-segment chain conformations change drastically due to the presence of cellulose nanocrystals (CNC)
CoPnocllyuusrieotnhsane nanocomposite membranes were effectively synthesized and tested for aqueoPuoslysuerpeatrhaatnioennoanf oegcogmaplbousmiteinmpermotberiannbeys wmeirceroefiffletrcatitvioenly. sCyNntChepsliazyeds aanndimtepsoterdtafnotr raoqleueinoucsonsterpoallriantgiopnooref esigzge aalnbdumfluinx.pWroetefiinndbtyhamtincaronfoilctoramtipoons.iCteNpCorpelfaoyrsmaantioimnpoocrctuarnst vrioalea isnpicnoondtraolldliencgompoproessitizioenamndecfhluaxn.isWme, wfinhdertehaastfnoarnnoecaotmPUpotshietenpuocrleeaftoiormn aatnidongroocwcutrhs via a spinodal decomposition mechanism, whereas for neat PU the nucleation and growth mechanism operates
Summary
Polyurethane (PU) has been widely applied in many industries as a versatile material due to its relatively easy manufacture, low cost, the accessible source of their raw materials and because they are typically used as glues, fibers, coatings and hoses among other applications. PU lacks enough good mechanical and thermal properties by itself, and porosity is in general not adequate for certain applications in membrane science. Polymer nanocomposites reinforced with a low fraction of nanofillers have received great attention due to the fascinating properties that they present, and could compete with those of the most advanced materials available in the market [4,5]. CNCs have been incorporated into a wide variety of polymer matrices as reinforcing fillers, due to their intrinsic properties such as nanoscale dimensions, high surface area, unique morphology, low density, high specific strength and Young’s modulus, as well as a very low coefficient of thermal expansion [7–9]
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