Nitrate removal from water by new polymeric adsorbent modified with amino and quaternary ammonium groups: Batch and column adsorption study

•New polymeric adsorbent NDQ is prepared for efficient removal of nitrate.•Its equilibrium adsorption capacity for nitrate is higher than other resins.•Batch and column adsorption of nitrate were deeply investigated.•Satisfactory repeated usability and low cost of NDQ shows good potential. A new pol...

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Bibliographic Details
Published in:Journal of the Taiwan Institute of Chemical Engineers 2016-09, Vol.66, p.191-199
Main Authors: Wu, Yan, Wang, Yi, Wang, Jinnan, Xu, Suqian, Yu, Liang, Philippe, Corvini, Wintgens, Thomas
Format: Article
Language:English
Subjects:
Batch and column experiments
New polymeric adsorbent
Nitrate removal
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Summary:•New polymeric adsorbent NDQ is prepared for efficient removal of nitrate.•Its equilibrium adsorption capacity for nitrate is higher than other resins.•Batch and column adsorption of nitrate were deeply investigated.•Satisfactory repeated usability and low cost of NDQ shows good potential. A new polymeric adsorbent (NDQ) modified with amino and quaternary ammonium groups was synthesized for the purpose of nitrate removal from water. Sorption kinetic and isotherm experiments were carried out in a series of batch experiments. Batch adsorption isotherms indicated that the maximum monolayer adsorption capacity of NDQ for nitrate was 221.8mg/g which was higher than that of many other adsorbents reported in literature. Both ion-exchange and hydrogen bond played important roles in nitrate removal. The enthalpy change (−12.32 to −9.65kJ/mol) and free energy change (−2.7 to −0.76kJ/mol) indicated an exothermic and spontaneous adsorption process. Moreover batch adsorption kinetic curves indicated that both film and intra-particle diffusion processes were rate-limiting in the nitrate adsorption. It was observed that the adverse effect of co-existing anions on nitrate removal followed the order of ‘SO42− > HCO3– > Cl–’. In order to quantify the influence of operational conditions on the treatment efficiency, a series of fixed bed column experiments were conducted at different bed heights, flow rates and influent concentrations, and the breakthrough curves at various operational conditions were simulated and analyzed using different mathematical models. Finally, the adsorption–desorption assay showed a promising reusability of the NDQ. [Display omitted]
ISSN:1876-1070
1876-1089
DOI:10.1016/j.jtice.2016.06.019