In Situ Charge Transfer at the Ag@ZnO Photoelectrochemical Interface toward the High Photocatalytic Performance of H₂ Evolution and RhB Degradation

Abstract: Designing an efficient hybrid structure photocatalyst for photocatalytic decomposition and hydrogen (H2) evolution has been considered a great choice to develop renewable technologies for clean energy production and environmental remediation. Enhanced charge transfer (CT) based on the interaction between a noble metal and a semiconductor is a crucial factor influencing the movement of photogenerated electron–hole pairs. Herein, we focus on the recent advances related to plasmon-enhanced noble metals and the se… Show more

“…[28][29][30] Hence, the combination of ZnO with noble metals to form noble metal/semiconductor hybrid nanostructures has been proposed as an efficient way to increase photocatalytic efficiency. [31][32][33] Bimetallic (such as AuPd, 24,[28][29][30]34,35,42 AuPt, [36][37][38][39] AgPd 40,41 ) NPs couple with semiconductors have better performance in comparison with monometallic NPs due to the synergistic effects. In particular, AuPd NPs have been proved to promote the photochemical activity signicantly.…”

One-pot, ligand-free, room-temperature synthesis of Au/Pd/ZnO nanoclusters with ultra-low noble metal loading and synergistically improved photocatalytic performances

“…[28][29][30] Hence, the combination of ZnO with noble metals to form noble metal/semiconductor hybrid nanostructures has been proposed as an efficient way to increase photocatalytic efficiency. [31][32][33] Bimetallic (such as AuPd, 24,[28][29][30]34,35,42 AuPt, [36][37][38][39] AgPd 40,41 ) NPs couple with semiconductors have better performance in comparison with monometallic NPs due to the synergistic effects. In particular, AuPd NPs have been proved to promote the photochemical activity signicantly.…”

One-pot, ligand-free, room-temperature synthesis of Au/Pd/ZnO nanoclusters with ultra-low noble metal loading and synergistically improved photocatalytic performances

“…Therefore, it is vital to develop SERS semiconductor substrates with high sensitivity, low cost, uniformity, and reproducibility. Compared with other metal oxide materials, Zinc oxide (ZnO) has been intensively carried out for SERS because of its enrichment, economical fabrication, nontoxicity, and photochemical stability 13,14 . Plasmonic nanoparticles are deposited Cite this article : Trang T N Q, Huong L T C, Duong T, Thu V T H. Ag-grafted on ZnO nanorod arrays using UV-assisted irradiation for enhanced SERS behavior in CV detection.…”

Ag-grafted on ZnO nanorod arrays using UV-assisted irradiation for enhanced SERS behavior in CV detection

“…23 Therefore, heterostructures comprising of semiconducting ZnO and plasmonic Ag with well-defined morphologies have attracted significant interest owing to their potential for providing new opportunities for optimising, tuning and/or enhancing the optical properties, electronic structure, electrical characteristics, and light-induced charge separation effects. [24][25][26] These plasmonic/dielectric heterostructures have gained considerable attention for studying their absorption spectral features, 27 photoluminescence, 28 Raman scattering, 29 second harmonic generation, 30 electrical conductivity, 31,32 and photocatalytic 33 and biological activity. 34,35 There have been extensive studies on the synthesis, characterization and applications of heteronanostructures; however, hardly any attention has been paid to the investigation of these aspects in microstructures.…”

Spectral characteristics upon harvesting plasmonic hot electrons at the Ag/ZnO heteromicrostructures