Figure 2 shows FETEM images of pure Fe3O4 microspheres with different magnifications together with the results of EDX analysis. The as-formed Fe3O4 consisted of well-separated microspheres with a mean particle size of 300 nm and a rough surface. EDX confirmed the presence of iron (Fe), oxygen
(O), and carbon (C) (signal from the organic solvent). Figure 2 FETEM and EDX images of Fe 3 O 4 particles. (a) Low and (b) high magnifications of FETEM images and (c) EDX analysis and Fe3O4 size distribution (inset). After coating with an ultrathin Y2O3:Tb3+ layer, the resulting core-shell Fe3O4@Y2O3:Tb3+ composite particles still maintained the spherical properties of the core Fe3O4 particles. On the other hand, the resulting Fe3O4@Y2O3:Tb3+ composite particles were slightly larger (approxi-mately Stattic ic50 325 nm) than the bare Fe3O4 microspheres because of the additional coated layer of Y2O3:Tb3+, as shown in Figure 3. Moreover, the core-shell Vactosertib molecular weight structure can also be observed clearly due to the small gap between the cores and shells. In addition, EDX analysis of the Fe3O4@Y2O3:Tb3+ composite particles revealed
the presence of yttrium (Y), terbium (Tb), iron (Fe), and oxygen (O) in the final composite particles. Figure 3 FETEM and EDX images of Fe 3 O 4 @Y 2 O 3 :Tb 3+ particles. (a) Low and (b) high magnifications of FETEM images and (c) EDX analysis and Fe3O4@Y2O3:Tb3+ size distribution (inset). XRD was used to investigate the structure and composition of the synthesized particles. Figure 4 shows XRD patterns of the bare Fe3O4 and Fe3O4@Y2O3:Tb3+ composite particles. The bare magnetite cores were indexed to the face-centered cubic (Fd3m space group) magnetite structure (JCPDS no. 19–0629) [15, 16]. In the case of Fe3O4@Y2O3:Tb3+ composite particles, in addition to the characteristic diffraction peaks of the cubic Fe3O4 structure, there were obvious diffraction
peaks indexed to the cubic phase of Y2O3 (JCPDS no. 86–1107, marked with ●), which suggests the successful crystallization of a Y2O3:Tb3+ thin layer on the surface of Fe3O4 particles. In addition, no additional peaks for other phases were detected, indicating that no reaction had occurred between the core and shell during the annealing process. Figure 4 X-ray diffraction patterns of bare Fe 3 O 4 and Fe 3 O 4 @Y 2 O 3 :Tb 3+ particles. Optical and magnetic properties click here of core-shell Fe3O4@Y2O3:Tb3+ particles According to Li et al. [20] for the Y/Tb binary systems, homogeneous nucleation of Tb(OH)CO3 occurs in priority and then the precipitation of Y(OH)CO3 largely proceeds via heterogeneous nucleation on already-formed Tb(OH)CO3 layer. Therefore, it was assumed that Tb(OH)CO3 was firstly fully deposited (1 mol%) on a Fe3O4 surface and then doped into the Y2O3 structure (after the annealing process). The PL properties of the core-shell Fe3O4@Y2O3:Tb3+ composite particles were ZD1839 in vivo characterized further by excitation and emission spectroscopy, as shown in Figure 5.