Comprehensive utilization of tailings is not only conducive to ensuring the sustainable use of resources but also can reduce the related environmental pollution. In the present work, a new utilization way of copper tailings was proposed and a novel composite (OMT-6) was prepared by modification of tailings with oxalic acid. The composite had super high Pb2+ adsorption capacity with the maximal Pb2+ removal capacity of 862.07 mg/g. Its Pb2+ removal behaviours followed pseudo-second-order kinetic equation and Langmuir model, suggesting that Pb2+ removal depended on monolayer adsorption. The surface of OMT-6 was rough and a lot of nanospheres were loaded on its surface. The composite had mesoporous structure and a larger specific surface area compared with tailings, the above characteristics of which facilitated Pb2+ removal. The major crystal structures of OMT-6 were transformed to CaC2O4•H2O and FeC2O4•2H2O after oxalic acid modification and Pb2+ could be removed by the ions exchange between Ca2+, Fe2+ and Pb2+. Pb2+ removal mechanisms of OMT-6 involved ion exchange, surface complexation and electrostatic attraction interaction, among which ion exchange played a key role. These results indicated that the prepared OMT-6 composite from copper tailings was an ideal material for Pb2+ removal from aqueous solution.
Keywords: Composite; Pb(2+) removal; Removal mechanisms; Tailings utilization.
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