S-scheme mechanism in the TiO2/Cu2O@Cu system toward selective degradation of an electron-rich dye pollutant under solar light

[Display omitted] •The plasmonic S-scheme TiO2/Cu2O@Cu heterojunction was successfully synthesized.•The TiO2/Cu2O@Cu showed superior selective degradation toward an electron-rich dye.•Cu doping, S-scheme and dye sensitization contributed to a selective degradation.•Electron and hole were the key act...

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Bibliographic Details
Published in:Journal of molecular liquids 2024-10, Vol.412, p.125830, Article 125830
Main Authors: Aflaki Jalali, Marzieh, Dadvand Koohi, Ahmad, Sheykhan, Mehdi
Format: Article
Language:English
Subjects:
Plasmonic resonance
S-scheme heterojunction
Selective photodegradation
TiO2
Wastewater treatment
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Summary:[Display omitted] •The plasmonic S-scheme TiO2/Cu2O@Cu heterojunction was successfully synthesized.•The TiO2/Cu2O@Cu showed superior selective degradation toward an electron-rich dye.•Cu doping, S-scheme and dye sensitization contributed to a selective degradation.•Electron and hole were the key active species causing selective degradation.•The Possible role of Cu and S-scheme mechanism for MB dye removal were discussed. This research aims to reach a selective nanocomposite based on Cu and TiO2 nanoparticles (NPs) through a sol–gel followed by chemical reduction. Various methods such as XRD, SEM, TEM, HRTEM, BET, Raman, FTIR, DRS, XPS and PL analysis were used to characterize the prepared NPs. The reduced nature of Cu in nanocomposite was evidenced by its X-ray photoelectron spectral characteristics and its HRTEM image. Due to the presence of Cu NPs, light absorption in solar radiation by nanocomposite was considerably enhanced and caused more efficient charge carriers separation. A CCD was used to evaluate the photoactivity of the solar-driven photocatalyst by degrading methylene blue (MB) as a single model electron-rich organic pollutant. In optimal conditions, the highest photocatalytic activity reached 95.64 %. In this study, band structure and reactive species scavenging results confirmed an S-scheme mechanism for charge carrier transfer during photodegradation. The plasmonic S-scheme TiO2/Cu2O@Cu heterojunction photocatalyst exhibited remarkably strong photocatalytic selectivity toward MB in binary mixtures of MB with eosin B and rhodamine B. A preference for degradation of MB over safranin (Saf) is confirmed by the faster degradation rate of MB than that of Saf. S-scheme mechanism, Cu doping and dye sensitization all contributed to outstanding selective photodegradation performance.
ISSN:0167-7322
DOI:10.1016/j.molliq.2024.125830