Bentonite polymer composite for water purification
Tóm tắt
A polyethylene glycol (PEG)–bentonite (BT) composite was prepared by direct polymerization of PEG in suspensions of BT. Based on detailed analyses using field-effect scanning electron microscopy, X-ray diffraction, surface area measurements and chemical methods, the obtained product was mainly composed of Ca-BT with a specific surface area of
$$4.13 \hbox { m}^{2} \hbox { g}^{-1}$$
. The optimal conditions for adsorption of
$$\hbox {Pb}^{2+}$$
and
$$\hbox {Cd}^{2+}$$
ions were found to be a PEG content of 0.1% and a contact time of 60 min. The sorption experiments were performed under various operating variables, including polymer concentration, pH and temperature. For both
$$\hbox {Pb}^{2+}$$
and
$$\hbox {Cd}^{2+}$$
, the adsorption equilibrium was described by the Freundlich model, which confirmed the presence of a heterogeneous system with irregular filling of the active centres. The maximum sorption capacities of BT–PEG for removal of
$$\hbox {Pb}^{2+}$$
and
$$\hbox {Cd}^{2+}$$
were found to be 22 and 18 mg
$$\hbox {g}^{-1}$$
, respectively. The rate constants calculated for the sorption of
$$\hbox {Pb}^{2+}$$
and
$$\hbox {Cd}^{2+}$$
were 6.29 and 6.67 g
$$\hbox {mg}^{-1} \hbox { min}^{-1}$$
, respectively, at
$$25^{\circ }\hbox {C}$$
. This study shows that the obtained sorbents based on BT may be used for treatment of waste water and could help resolve environmental protection issues.
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