Abstract
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•Different Fe3O4@PDA spheres were prepared by in situ polymerization method.•The Fe3O4@PDA spheres show great adsorption capacity for the removal of U(VI).•Fe3O4@PDA nano-spheres own its highest adsorption capacity for U(VI) removal.•The U(VI) adsorption onto Fe3O4@PDA spheres is exothermic and spontaneous.•The adsorption is achieved via interaction between U(VI) and functional groups.
In this work, two kinds of core–shell Fe3O4@PDA materials with different morphologies were successfully prepared by a simple in situ polymerization method based on two kinds of pristine Fe3O4 spheres, which were obtained by hydrothermal method. Among the four obtained samples, Fe3O4@PDA porous nano-spheres (MNS-4) have the best U(VI) entrapment performance, which can not only be owing to the structure characteristics (higher porosity and lower density) but also to the PDA shell with large amount of functional groups. Additionally, the maximum removal capacity of MNS-4 for U(VI) entrapment can be of 193.27 mg·g−1 at 298 K, which exceeds the adsorption capacity of most other reported magnetic materials. Moreover, the solution pH values have a significant effect on the adsorption performance of the adsorbents for U(VI) pre-concentration while that originated from ionic strength can be negligible, suggesting that the adsorption process can be achieved through inner-sphere surface complexation. Thermodynamic studies reveal that the U(VI) adsorption process is exothermic and spontaneous. The analysis of adsorption mechanism indicates that U(VI) pre-concentration process can be achieved by the interactions between OH groups, pyridinic N and CNH2 and U(VI). This work not only offers a new point of synthesizing undertaking adsorbents with targeting structures, but also provides a facile and versatile approach towards designing Fe3O4-based hybrid materials for their potential environmental applications.