Removal of pharmaceuticals from water by clay-cationic starch sorbents

Significant concerns have been raised up due to the presence of organic micropollutants in surface waters. The ability of two polymer-clay sorbents based on a functionalized cationic starch was examined for the removal of three pharmaceuticals: atenolol, sulfamethoxazole and diclofenac sodium. In ba...

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Bibliographic Details
Published in:Journal of cleaner production 2018-07, Vol.190, p.703-711
Main Authors: Lozano-Morales, Virginia, Gardi, Ido, Nir, Shlomo, Undabeytia, Tomás
Format: Article
Language:English
Subjects:
Cationic starch
Clay-polymer composites
Emerging pollutants
Filtration
Modeling
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Summary:Significant concerns have been raised up due to the presence of organic micropollutants in surface waters. The ability of two polymer-clay sorbents based on a functionalized cationic starch was examined for the removal of three pharmaceuticals: atenolol, sulfamethoxazole and diclofenac sodium. In batch experiments, the complex which exhibited a planar conformation of the polymer on the clay surface and higher cationic charge density showed higher sorption of diclofenac and sulfamethoxazole over those of the composite with a loops and tails configuration, but similar with atenolol. The introduction of functional moieties on the polymers that are capable to create a network of hydrogen-bonds with the pollutants promoted their removal as revealed by thermal and infrared techniques: diclofenac molecules formed an ion pair including hydrogen bonds through their secondary amine groups; sulfamethoxazole sorbed by strong electrostatic interactions followed by proton transfer involving its sulphon-nitrogen group and the hydroxyl moieties of the composite. Filtration experiments showed a better performance of the columns made of the composite with higher cationic charge density on the removal of diclofenac and sulfamethoxazole over that of granular activated carbon. The filtration processes were successfully modeled by using an adsorption-convection model which enabled predictions under different operational conditions used in drinking water plants. Experimental removal of diclofenac by filtration within the range found in environmental concentrations was in good agreement with the predicted amounts. [Display omitted] •Clay-polymer composites adsorbed anionic PhAcs very efficiently.•Sorption mechanisms comprised hydrogen-bonds and electrostatic forces.•Sorption of cationic PhAcs also occurred by hydrophobic interactions.•Filtration of anionic PhAcs was more efficient than with GAC.•Success in filtration modeling enabled predictions under other scenarios.
ISSN:0959-6526
1879-1786
DOI:10.1016/j.jclepro.2018.04.174