Self-Assembly of Three-Dimensional Hyperbranched Magnetic Composites and Application in High-Turbidity Water Treatment.

In order to improve dispersibility, polymerization characteristics, chemical stability, and magnetic flocculation performance, magnetic FeO is often assembled with multifarious polymers to realize a functionalization process. Herein, a typical three-dimensional configuration of hyperbranched amino acid polymer (HAAP) was employed to assemble it with FeO, in which we obtained three-dimensional hyperbranched magnetic amino acid composites (FeO@HAAP). The characterization of the FeO@HAAP composites was analyzed, for instance, their size, morphology, structure, configuration, chemical composition, charged characteristics, and magnetic properties. The magnetic flocculation of kaolin suspensions was conducted under different FeO@HAAP dosages, pHs, and kaolin concentrations. The embedded assembly of HAAP with FeO was constructed by the N-O bond according to an X-ray photoelectron energy spectrum (XPS) analysis. The characteristic peaks of -OH (3420 cm), C=O (1728 cm), Fe-O (563 cm), and N-H (1622 cm) were observed in the Fourier transform infrared spectrometer (FTIR) spectra of FeO@HAAP successfully. In a field emission scanning electron microscope (FE-SEM) observation, FeO@HAAP exhibited a lotus-leaf-like morphological structure. A vibrating sample magnetometer (VSM) showed that FeO@HAAP had a relatively low magnetization () and magnetic induction (); nevertheless, the ferromagnetic FeO@HAAP could also quickly respond to an external magnetic field. The isoelectric point of FeO@HAAP was at 8.5. FeO@HAAP could not only achieve a 98.5% removal efficiency of kaolin suspensions, but could also overcome the obstacles induced by high-concentration suspensions (4500 NTU), high pHs, and low fields. The results showed that the magnetic flocculation of kaolin with FeO@HAAP was a rapid process with a 91.96% removal efficiency at 0.25 h. In an interaction energy analysis, both the U and U showed electrostatic repulsion between the kaolin particles in the condition of a flocculation distance of <30 nm, and this changed to electrostatic attraction when the separation distance was >30 nm. As FeO@ HAAP was employed, kaolin particles could cross the energy barrier more easily; thus, the fine flocs and particles were destabilized and aggregated further. Rapid magnetic separation was realized under the action of an external magnetic field.