The radiological toxicity of uranium in nuclear industrial wastewater poses a long-term threat to environment, thus the effective separation of radionuclide from wastewater is very important for environmental safety. Herein, the macroporous ion-imprinted chitosan foams (ICFs) were synthesized by the combination of the facile freezing-drying and ion-imprinting techniques. Compared with non-imprinted chitosan foam, the ICFs showed much higher adsorption capacities (qm = 248.9-253.6 mg/g) and better adsorption selectivity for U(VI) owing to their smart recognition of the target ions for matching the cavities formed during U(VI)-imprinting process. The adsorption kinetics could be fitted by pseudo-second-order model; whereas the adsorption isotherms could be described by Langmuir model, indicating chemisorption or complexation mechanism. The FT-IR and XPS analysis further confirms that the coordination between U(VI) and the active sites (amine and hydroxyl groups) is the main adsorption mechanism. The thermodynamic parameters suggest that the adsorption of U(VI) is endothermic and spontaneous. This work provides new insights for the design of novel macroporous biosorbents with both high adsorption capacity and excellent adsorption selectivity for U(VI) biosorption from wastewater.
Keywords: Chitosan foams; Ion-imprinting; Uranium adsorption.
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