Abstract
Aqueous dispersions of magnetic nanocomposites have been proposed as draw electrolytes in forward osmosis. One possible approach for the production of nanocomposites based on magnetite nanoparticles and sodium polyacrylate is the synthesis of the magnetic iron oxide by coprecipitation or oxidative precipitation in the presence of an excess of the polymer. In this work, we explored the effect of the polymer proportion on the nanomaterials produced by these procedures. The materials obtained were compared with those obtained by the coating of magnetite nanocrystals produced beforehand with the same polymer. The samples were characterized by chemical analysis, photon correlation spectroscopy, thermogravimetry, X-ray diffraction, infrared spectroscopy, transmission electron microscopy, and magnetometry. The general trend observed is that the polymers heavily modify the texture of the magnetic material during the synthesis, with a drastic reduction of the particle size and magnetic response. The polycrystalline texture that is generated permits the incorporation of the polymer both on the external surface and in the intergranular space. The aqueous dispersions of the nanocomposites were highly stable, with a hydrodynamic size that was roughly independent of the polymer/magnetite ratio. Such dispersions show an osmotic pressure that is proportional to the concentration of the polymer. Interestingly, the proportionality constant was similar to that of the free polymer only in the case of the samples prepared by oxidative precipitation, being lower in the case of the samples prepared by coprecipitation. Finally, the possibilities of using these materials as draw electrolytes in forward osmosis will be briefly discussed.
Highlights
Forward osmosis (FO) is considered a technology for water desalination and the reuse of wastewater with great potential [1,2,3,4,5]
The surface of the magnetic nanoparticles (MNPs) was activated by acid treatment as follows [40]: 300 mL of 2 M of HNO3 were added to the decanted MNP and redispersed by stirring; the supernatant was removed after the magnetic sedimentation, and the MNP were redispersed in 75 mL of 1 M Fe(NO3)3 and 130 mL of water, and the slurry was heated at 90 ◦C for 30 min
The polyacrylate coating developed in this work afforded stable aqueous colloids at a pH of around 7, the amount of coating material on the nanoparticles surface was very low: 6% for the 11-nm MNP obtained by coprecipitation, and 1% for the 30-nm MNP obtained by oxidative precipitation
Summary
Forward osmosis (FO) is considered a technology for water desalination and the reuse of wastewater with great potential [1,2,3,4,5]. The forward osmosis process uses an electrolyte of high osmotic pressure (draw electrolyte) to drive the water molecules through a membrane from the waste or seawater instead of the high pressure pumps used in the standard reverse osmosis (RO). Thermoresponsive substances that are able to produce sols of high osmotic pressure and split in two phases with small changes in temperature could be used as draw solutes In this case, the water was advantageously separated from the water-rich phase. The objective is to determine the maximum osmotic pressure that is compatible with the minimum magnetic response that is needed for separation in the model system magnetite/poly(sodium acrylate) (Fe3O4/PAANa) This approach requires the preparation of a range of magnetic nanocomposites (MNC) of magnetic nanoparticles of different sizes and different PAANa/Fe3O4 ratios, as well as characterizing them and comparing their osmolalities and magnetic properties. The general picture obtained will inform regarding the real capability of FO in water remediation when the recovery of the treated water had to be done exclusively by magnetic forces
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