Structural, morphological, ferromagnetic and photoluminescence properties of Fe-doped ZnO, prepared by hydrothermal route

“…5b). Similar results were reported in the literature [56][57][58][59]. According to these studies, the incorporation of metallic ions into the host matrix increases the density of structural defects and favors the formation of lower energy levels in the conduction band of the semiconductor.…”

“…According to these studies, the incorporation of metallic ions into the host matrix increases the density of structural defects and favors the formation of lower energy levels in the conduction band of the semiconductor. For instance, the presence of Fe 3+ ions decreases the number of V o and O i ions compared to undoped ZnO due to the formation of local defects represented by one cation vacancy (V " Zn ) every two Fe 3+ dopant ions in order to charge balance [56]. Upon Ni 2+ incorporation, the intensity of PL emission also increases because of distortion centers in the ZnO lattice resulting from the presence of [NiO 6 ] clusters [60].…”

Efficient Ni and Fe doping process in ZnO with enhanced photocatalytic activity: A theoretical and experimental investigation

“…5b). Similar results were reported in the literature [56][57][58][59]. According to these studies, the incorporation of metallic ions into the host matrix increases the density of structural defects and favors the formation of lower energy levels in the conduction band of the semiconductor.…”

“…According to these studies, the incorporation of metallic ions into the host matrix increases the density of structural defects and favors the formation of lower energy levels in the conduction band of the semiconductor. For instance, the presence of Fe 3+ ions decreases the number of V o and O i ions compared to undoped ZnO due to the formation of local defects represented by one cation vacancy (V " Zn ) every two Fe 3+ dopant ions in order to charge balance [56]. Upon Ni 2+ incorporation, the intensity of PL emission also increases because of distortion centers in the ZnO lattice resulting from the presence of [NiO 6 ] clusters [60].…”

Efficient Ni and Fe doping process in ZnO with enhanced photocatalytic activity: A theoretical and experimental investigation

“…At this stage, faster dissolution of ZnO at six prismatic edges and growth of prism faces along six m-planes result in pointed tips, as shown in Figure 10. Cernea 107 and his group have prepared Fe-doped ZnO nanoflower-like structures, and other group of Mihalache et al 108 has also synthesized Fe-doped ZnO nanoflower-like structures. Furthermore, Turkylmaz 109 and his group have prepared Ni-, Fe-, Mn-, and Ag-doped ZnO nanoplates through the hydrothermal approach.…”

Progress on Transition Metal-Doped ZnO Nanoparticles and Its Application

“…It was widely reported that Fe-doping promotes the morphological evolution of some nanostructures, such as Fe-doped ZnO. [38] A diversity of types of doped g-C 3 N 4 nanostructures including nanosheets, nanotubes, mesostructures, nanorods, and nanofibers were synthesized by cocalcination of precursor and the doping element. [39][40][41] The difference in our method was that presynthesized bulk g-C 3 N 4 was cosonication with FeCl 3 rather than cocalcination of precursor and the doping metal ions, achieving a fusiform structure.…”

Chlorogenic Acid‐Conjugated Nanoparticles Suppression of Platelet Activation and Disruption to Tumor Vascular Barriers for Enhancing Drug Penetration in Tumor