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Maevskaya, Maria V. [Author]; Rudakova, Aida V. [Author]; Koroleva, Alexandra V. [Author]; Sakhatskii, Aleksandr S. [Author]; Emeline, Alexei V. [Author]; Bahnemann, Detlef W. [Author]

Effect of the Type of Heterostructures on Photostimulated Alteration of the Surface Hydrophilicity: TiO2/BiVO4 vs. ZnO/BiVO4 Planar Heterostructured Coatings - [published Version]

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  • Media type: Text; E-Article
  • Title: Effect of the Type of Heterostructures on Photostimulated Alteration of the Surface Hydrophilicity: TiO2/BiVO4 vs. ZnO/BiVO4 Planar Heterostructured Coatings
  • Contributor: Maevskaya, Maria V. [Author]; Rudakova, Aida V. [Author]; Koroleva, Alexandra V. [Author]; Sakhatskii, Aleksandr S. [Author]; Emeline, Alexei V. [Author]; Bahnemann, Detlef W. [Author]
  • Published: Basel : MDPI, 2021
  • Published in: Catalysts 11 (2021), Nr. 12 ; Catalysts
  • Issue: published Version
  • Language: English
  • DOI: https://doi.org/10.15488/14540; https://doi.org/10.3390/catal11121424
  • Keywords: Surface energy ; Charge transfer ; Heterojunctions ; Photostimulated hydrophilicity ; Charge separation ; Heterostructures ; Work function ; Metal oxide surfaces
  • Origination:
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  • Description: Here, we report the results of comparative studies of the photostimulated hydrophilic behavior of heterostructured TiO2 /BiVO4 and ZnO/BiVO4, and monocomponent TiO2 and ZnO nanocoating surfaces. The chemical composition and morphology of the synthesized nanocoat-ings were characterized by XPS, SEM, and AFM methods. The electronic energy structure of the heterostructure components (band gap, top of the valence band, bottom of the conduction band, and Fermi level position) was determined on the basis of experimental results obtained by XPS, UV-V absorption spectroscopy and Kelvin probe methods. According to their electronic energy structure, the ZnO/BiVO4 and TiO2 /BiVO4 heterostructures correspond to type I and type II het-erostructures, respectively. The difference in the type of heterostructures causes the difference in the charge transfer behavior at heterojunctions: the type II TiO2 /BiVO4 heterostructure favors and the type I ZnO/BiVO4 heterostructure prevents the photogenerated hole transfer from BiVO4 to the outer layer of the corresponding metal oxide. The results of the comparative studies show that the interaction of the photogenerated holes with surface hydroxy-hydrated multilayers is responsible for the superhydrophilic surface conversion accompanying the increase of the surface free energy and work function. The formation of the type II heterostructure leads to the spectral sensitization of the photostimulated surface superhydrophilic conversion.
  • Access State: Open Access