AI Article Synopsis
- * A unique 0D-2D hierarchical nanostructured heterojunction was developed by growing BiOCl (p-type) nanosheets on BiVO (n-type) nanoparticles, leading to a significant increase in the degradation efficiency of rhodamine B dye from about 32% to 99.5% in just 55 minutes.
- * The findings highlight that the p-n heterojunction design improves the separation of photogenerated carriers, with ·O and h species identified as key active agents in the degradation process, suggesting a promising avenue for
Article Abstract
The construction of hybrid heterojunction photocatalysts is an effective strategy to improve the utilization of photogenerated carriers and photocatalytic activity. To enhance the separation distance of photogenerated carriers and accelerate the effective separation at the heterojunction of the interface, a unique 0D-2D hierarchical nanostructured p-n heterojunction was successfully fabricated in this work. BiOCl (BOC) nanosheets (p-type) were in situ grown on BiVO (BVO) nanoparticles (n-type) using the microemulsion-calcination method for highly efficient visible-light-driven organic dye degradation. Compared with pure BVO (the degradation rate of rhodamine B (RhB): about 32.0% in 55 min, the mineralization rate: 24.9% in 120 min), the RhB degradation rate can reach about 99.5% in 55 min and the mineralization rate of 62.1% in 120 min by utilizing BVO/25%BOC heterojunction photocatalyst under visible light irradiation. Various characterizations demonstrate that the formation of BVO/BOC p-n heterojunction greatly facilitates photogenerated carriers separation efficiency. Meanwhile, the results of the scavenging experiments and electron spin resonance tests indicate that ·O and h are the prominent active species for Rh B degradation. In addition, possible degradation pathways for Rh B were proposed using LC-MS tests. This work proves that building low dimensional p-n heterojunction photocatalysts is a promising strategy for developing photocatalysts with high efficiency.
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| http://dx.doi.org/10.1016/j.chemosphere.2024.141658 | DOI Listing |
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