Abstract:

A new absorbent for the removal of fluoride from drinking water was prepared by using lanthanum loaded chitosan beads crosslinked with ethylene glycol diglycidyl ether (EGDE)replacing glutaraldehyde (GLA).Static and dynamic adsorption of fluoride onto absorbents (CEB-La)was investigated, respectively. The effects of various physico-chemical parameters were studied. The results of static experiment showed that the optimal adsorption conditions were pH7. 0， water temperature 50℃, contact time 60 min, and oscillation frequency 120 r·min^-1. Treating the water containing F^- of 10 mg·L^-1 with CEB-La under this condition, the defluoridation rate was up to 92.9% and the residual concentration of F^- was 0.71 mg·L^-1, lower than 1.0 mg·L^-1. Furthermore, the adsorption isotherm could be described by the Langmuir and Freundlich models and the maximum adsorption capacity for F^- was 25.7 mg·g^-1. Sorption dynamics study revealed that the pseudo-second-order equation was suitable to describe the kinetics process of fluoride ions sorption onto the adsorbent. The used adsorbents could be regenerated by chelating with lanthanum after soaking in 0.5 mol·L^-1 of sodium hydroxide for 6 h. The removal efficiencies of F^- were related to the co-existing anions. In particular, the presence of CO^{2 -}₃ and HCO^-₃ led to a markedly decreased adsorption capacity of CEB-La for F^-. The results of dynamic experiment demonstrated that CEB-La was suitable for treating drinking water containing F^- of 2—15 mg· L^-1 when the volumetric flow rate was 3 ml·min^-1. Column kinetics were described by the Thomas model and the dynamic adsorption capacity was 3.67 mg·g^-1. Therefore, the absorbent is easy to regenerate, of low-cost, and has superior defluoridation properties, showing that it is a potential material for F^- removal in practice.