Composite nanomaterials have been widely used in catalysis because of their attractive properties and various functions. Among them, the preparation of composite nanomaterials by redox has attracted much attention. In this work, pure CuO was prepared by liquid phase reduction with Cu(NO) as the copper source, NaOH as a precipitator, and sodium ascorbate as the reductant. With Fe(NO) as the iron source and solid-state phase reaction between Fe and CuO, CuO-FeO nanocatalysts with different Fe/Cu ratios were prepared. The effects of the Fe/Cu ratio on the structure of CuO-FeO nanocatalysts were studied by means of X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), ultraviolet confocal Raman (Raman), scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS, XAES), and hydrogen temperature-programmed reduction (H-TPR). Furthermore, the structure-activity relationship between the structure of CuO-FeO nanocatalysts and the performance of formaldehyde ethynylation was discussed. The results show that Fe deposited preferentially on the edges and corners of the CuO surface, and a redox reaction between Fe and Cu occurred, forming CuO-FeO nanoparticles containing Cu, Cu, Fe, and Fe. With the increase of the Fe/Cu ratio, the content of CuO-FeO increased. When the Fe/Cu ratio reached 0.8, a core-shell structure with CuO inside and a CuO-FeO coating on the outside was formed. Because of the large physical surface area and the heterogeneous structure formed by CuO-FeO, the formation of nonactive Cu metal is inhibited, and the most active species of Cu are exposed on the surface, showing the best formaldehyde ethynylation activity.
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| http://dx.doi.org/10.3390/nano9091301 | DOI Listing |
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