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Abstract
Heterojunction copper–zinc oxide catalysts were prepared by a hybrid two-step methodology comprising hydrothermal growth of ZnO nanorods (ZnO-NR) followed by deposition of Cu2O nanoparticles using an advanced gas deposition technique (AGD). The obtained bicatalysts were characterized by SEM, AFM, XRD, XPS, PL and spectrophotometry and revealed well-dispersed and crystalline Cu2O nanoparticles attached to the ZnO-NR. The adsorption properties and photocatalytic degradation of Orange II dye in water solutions were measured. It was found that the bicatalysts exhibited a conversion rate and quantum yield that both were about 50% higher compared with ZnO-NR alone, which were attributed to the intrinsic electric field created at the p–n junction formed at the Cu2O/ZnO interface facilitating charge separation of electron–hole pairs formed upon interband photon absorption. The interpretation was evidenced by efficient quenching of characteristic deep level ZnO photoluminescence bands and photoelectron core-level energy shifts. By comparisons with known energy levels in Cu2O and ZnO, the effect was found to be most pronounced for the non-polar ZnO-NR side facets, which accounted for about 95% of the exposed surface area of the catalyst and hence the majority of dye adsorption. It was also found that the dye adsorption capacity of the ZnO nanorods increased considerably after Cu2O deposition thereby facilitating the oxidation of the dye. The results imply the possibility of judiciously aligning band edges on structurally controlled and well-connected low-dimensional semiconductor nanostructures using combined two-step synthesis techniques, where in particular vacuum-based techniques such as AGD allow for growth of well-connected nanocrystals with well developed heterojunction interfaces.
Highlights
Ensuring adequate management of water resources is one of the UN's Sustainable Development Goals.[1]
It was found that the bicatalysts exhibited a conversion rate and quantum yield that both were about 50% higher compared with Zinc oxide (ZnO) nanorods (ZnO-NR) alone, which were attributed to the intrinsic electric field created at the p–n junction formed at the Cu2O/ZnO interface facilitating charge separation of electron–hole pairs formed upon interband photon absorption
Analysis of the scanning electron microscopy (SEM) images revealed that about 95% of the exposed surface area were side faces, and only about 5% are polar top faces—the average length of the hexagonal (0001) top facets is approx. 40 nm, while the average side length of the rods is approximately 300 nm. This in uences the relevant band alignments for the Cu2O–ZnO np-junctions that governs the observed physicochemical properties
Summary
Ensuring adequate management of water resources is one of the UN's Sustainable Development Goals.[1]. Cu2O coated ZnO-NRs, respectively, can be attributed to O–H,24 and, in the case of Cu2O-coated samples, to Cu(OH)2.25 The latter assignment is consistent with the much higher relative intensity of the high-energy 531.7 eV O 1s peak (see Fig. 3, panel (d)).
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