Abstract
The complex synthesis process, high cost, toxicity and difficult separation of traditional adsorbents have limited their application for the removal of emerging organic contaminants (EOCs) from the aquatic environment. A completely bio-based alginate reinforced with cellulose nanocrystals hydrogel via Fe2+ cross-linking (CNC/Alg-Fe2+), was successfully fabricated as an effective adsorbent under unique low temperature heat treatment (100 °C) for tetracycline (TC) removal. The metal ions (Fe3+, Fe2+ and Ca2+) enabled bindings with hydroxyl, sulfate half ester and carboxyl groups coexisted on CNC/Alg surface via chelation, strong hydrogen bonds and electrostatic interactions. Among composite materials with varied cation cross-linkers, hydrogel cross-linked with Fe2+ showed the maximum adsorption capacity of TC (741.66 mg·g−1), circa 1.9 and 6.9 times higher than that of hydrogel cross-linked with Fe3+ (394.16 mg·g−1) and Ca2+ (108.14 mg·g−1) respectively at 298 K, due to enhanced chelation between Fe2+ and TC. The efficient adsorption of TC was attributed to surface complexation, cation bridging, n-π electronic donator-acceptor interactions, hydrogen bonds and electrostatic interactions synergistically. Besides, adsorption capacity of CNC/Alg-Fe2+ retained 84.6% after 5 regeneration cycles indicating high reusability. This study provides a simple but effective bio-based hydrogel absorbent with stable structure, ultrahigh adsorption capacity, excellent reusability and easy-separation for the purification of TC-containing biomedical wastewater.
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