In this study, magnetic Fe3O4@Mg(OH)(2) composites were fabricated for the removal of Cu(II) ions from aqueous solutions. The composites demonstrated significant adsorption capacity and could be efficiently separated through external magnetic fields. The effective adsorption properties and magnetic separation make them suitable for treating copper-contaminated water.
In this study, we fabricated magnetic Fe3O4@Mg(OH)(2) composites through the seed deposition technique to achieve Cu(II) ion removal from aqueous solutions. As indicated by the characterization results, three-dimensional flower-like spheres composed of external Mg(OH)(2) were formed, with nano-Fe3O4 particles uniformly embedded in the flower petals of the spheres. The efficacy of Fe3O4@Mg(OH)(2)-3 in Cu(II) ion removal was examined through batch experiments. The impact of solution pH on removal efficiency was examined, and the pseudo-second-order model and the Langmuir model provided good fits to the adsorption kinetics and isotherm data, respectively. Remarkably, Fe3O4@Mg(OH)(2)-3 exhibited a significant removal capacity of 1051.65 mg g(-1) for Cu(II) ions. Additionally, the composite displayed a notable saturation magnetization value of 17.3 emu g(-1), facilitating isolation from sample solutions through external magnetic fields after Cu(II) ion absorption. At the solid-liquid interface, a mechanism involving ion exchange between Mg(II) and Cu(II) cations was realized as the mode of Cu(II) ion removal. The composites' effective adsorption properties and rapid magnetic separation highlighted their suitability for use in treating copper-contaminated water.
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