Controllable Compositions and Structures of Fe<i><sub>x</sub></i>O<i><sub>y</sub></i>@SiO<sub>2</sub>@C-Ni Hybrids with a Silica Layer as a Mineral Redox Buffer
Lei Ding, Liting Yang, Jingli Xu, Jing Zheng, Min Zhang
Abstract
Mineral redox buffer is a vital concept in geology that can be applied to modulate hybrid compositions and generate nanostructures with expected morphology. Here, via combining a dual coating of an inorganic silica and organic resorcinol-formaldehyde-Ni2+ (RF-Ni2+) layer on α-Fe2O3 spindles with a subsequent calcination process, core–shell FexOy@SiO2@C-Ni composites with multicompositional structures were fabricated as efficient catalysts for 4-nitrophenol (4-NP) reduction. Notably, the silica layer as a redox buffer between hematite cores and the RF-Ni2+ shell played a crucial role in modulating the compositions and structures of the FexOy@SiO2@C-Ni. Without the silica layer, Fe3O4-Ni/C composites with Ni nanoparticles trapped into the Fe3O4 cores were generated. Moreover, a significant impact of the calcination temperature on morphologies and compositions of the FexOy@SiO2@C-Ni catalysts along with their catalytic performances has been verified. As a result, the catalyst annealed at 500 °C exhibited a high magnetic property and optimized morphology with high-density small nickel nanoparticles (∼11.6 nm), showing remarkably enhanced catalytic activity compared to the Fe3O4-Ni/C composites and excellent recyclability with a high conservation of about 92%. Furthermore, this synthetic strategy shows significant potential to modulate the nanostructures and phases of other multivalent metal oxide nanocomposites.