Effect of the TiO2–ZnO Heterostructure on the Photoinduced Hydrophilic Conversion of TiO2 and ZnO Surfaces

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Aida V. Rudakova
  • Alexei V. Emeline
  • Detlef Bahnemann

Research Organisations

External Research Organisations

  • Saint Petersburg State University
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Details

Original languageEnglish
Pages (from-to)8884-8891
Number of pages8
JournalThe Journal of Physical Chemistry C
Volume123
Issue number14
Early online date19 Mar 2019
Publication statusPublished - 11 Apr 2019

Abstract

The present study demonstrates the effect of the composition and structure of TiO 2-ZnO heterostructured coatings on the photoinduced hydrophilic conversion of TiO 2 and ZnO surfaces. It has been observed that the kinetic parameters of the photoinduced hydrophilic conversion can be significantly changed. Based on the analysis of the experimental data and the proposed mechanism, it is concluded that the ratio between the surface concentrations of electrons and holes participating in the photoinduced generation and deactivation of hydrophilic surface sites plays the major role in this alteration of the surface hydrophilicity of such heterostructured coatings. The ratio between the surface concentrations of electrons and holes can be changed considerably by the formation of the so-called type II heterojunction between TiO 2 and ZnO, yielding an effective charge separation. The proposed approach based on the creation of these type II heterostructures seems to be promising and productive both for fundamental studies of the photoinduced surface superhydrophilicity and for the application of self-cleaning coatings with controlled wettability.

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Cite this

Effect of the TiO2–ZnO Heterostructure on the Photoinduced Hydrophilic Conversion of TiO2 and ZnO Surfaces. / Rudakova, Aida V.; Emeline, Alexei V.; Bahnemann, Detlef.
In: The Journal of Physical Chemistry C, Vol. 123, No. 14, 11.04.2019, p. 8884-8891.

Research output: Contribution to journalArticleResearchpeer review

Rudakova AV, Emeline AV, Bahnemann D. Effect of the TiO2–ZnO Heterostructure on the Photoinduced Hydrophilic Conversion of TiO2 and ZnO Surfaces. The Journal of Physical Chemistry C. 2019 Apr 11;123(14):8884-8891. Epub 2019 Mar 19. doi: 10.1021/acs.jpcc.8b12125
Rudakova, Aida V. ; Emeline, Alexei V. ; Bahnemann, Detlef. / Effect of the TiO2–ZnO Heterostructure on the Photoinduced Hydrophilic Conversion of TiO2 and ZnO Surfaces. In: The Journal of Physical Chemistry C. 2019 ; Vol. 123, No. 14. pp. 8884-8891.
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title = "Effect of the TiO2–ZnO Heterostructure on the Photoinduced Hydrophilic Conversion of TiO2 and ZnO Surfaces",
abstract = "The present study demonstrates the effect of the composition and structure of TiO 2-ZnO heterostructured coatings on the photoinduced hydrophilic conversion of TiO 2 and ZnO surfaces. It has been observed that the kinetic parameters of the photoinduced hydrophilic conversion can be significantly changed. Based on the analysis of the experimental data and the proposed mechanism, it is concluded that the ratio between the surface concentrations of electrons and holes participating in the photoinduced generation and deactivation of hydrophilic surface sites plays the major role in this alteration of the surface hydrophilicity of such heterostructured coatings. The ratio between the surface concentrations of electrons and holes can be changed considerably by the formation of the so-called type II heterojunction between TiO 2 and ZnO, yielding an effective charge separation. The proposed approach based on the creation of these type II heterostructures seems to be promising and productive both for fundamental studies of the photoinduced surface superhydrophilicity and for the application of self-cleaning coatings with controlled wettability. ",
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note = "Funding Information: The present study was performed within the project “Establishment of the Laboratory {\textquoteleft}Photoactive Nanocomposite Materials{\textquoteright}” no. 14.Z50.31.0016 supported by a Mega Grant of the Government of the Russian Federation and a research grant of the Saint Petersburg State University (Pure ID 39054581). A.V.R. thanks the RFBR no. 18-03-00855\18 grant, which supported the studies of photoinduced hydrophilicity of composite thin films. The authors are also grateful to the RC “Nanophotonics” (personally to Dr. Maxim Lozhkin), RC “Nanotechnology” (personally to Dr. Vladimir Mikhailovski), RC “X-ray Diffraction Studies” (personally to Dr. Igor Kasatkin), and RC “Centre for Physical Methods of Surface Investigation” (personally to Dr. Alexandra Koroleva) of the Research Park at Saint Petersburg State University for the helpful assistance in conducting synthesis and characterization of the samples. The authors thank Dr. Evgenii Ubyivovk for performing the TEM analysis.",
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AU - Rudakova, Aida V.

AU - Emeline, Alexei V.

AU - Bahnemann, Detlef

N1 - Funding Information: The present study was performed within the project “Establishment of the Laboratory ‘Photoactive Nanocomposite Materials’” no. 14.Z50.31.0016 supported by a Mega Grant of the Government of the Russian Federation and a research grant of the Saint Petersburg State University (Pure ID 39054581). A.V.R. thanks the RFBR no. 18-03-00855\18 grant, which supported the studies of photoinduced hydrophilicity of composite thin films. The authors are also grateful to the RC “Nanophotonics” (personally to Dr. Maxim Lozhkin), RC “Nanotechnology” (personally to Dr. Vladimir Mikhailovski), RC “X-ray Diffraction Studies” (personally to Dr. Igor Kasatkin), and RC “Centre for Physical Methods of Surface Investigation” (personally to Dr. Alexandra Koroleva) of the Research Park at Saint Petersburg State University for the helpful assistance in conducting synthesis and characterization of the samples. The authors thank Dr. Evgenii Ubyivovk for performing the TEM analysis.

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N2 - The present study demonstrates the effect of the composition and structure of TiO 2-ZnO heterostructured coatings on the photoinduced hydrophilic conversion of TiO 2 and ZnO surfaces. It has been observed that the kinetic parameters of the photoinduced hydrophilic conversion can be significantly changed. Based on the analysis of the experimental data and the proposed mechanism, it is concluded that the ratio between the surface concentrations of electrons and holes participating in the photoinduced generation and deactivation of hydrophilic surface sites plays the major role in this alteration of the surface hydrophilicity of such heterostructured coatings. The ratio between the surface concentrations of electrons and holes can be changed considerably by the formation of the so-called type II heterojunction between TiO 2 and ZnO, yielding an effective charge separation. The proposed approach based on the creation of these type II heterostructures seems to be promising and productive both for fundamental studies of the photoinduced surface superhydrophilicity and for the application of self-cleaning coatings with controlled wettability.

AB - The present study demonstrates the effect of the composition and structure of TiO 2-ZnO heterostructured coatings on the photoinduced hydrophilic conversion of TiO 2 and ZnO surfaces. It has been observed that the kinetic parameters of the photoinduced hydrophilic conversion can be significantly changed. Based on the analysis of the experimental data and the proposed mechanism, it is concluded that the ratio between the surface concentrations of electrons and holes participating in the photoinduced generation and deactivation of hydrophilic surface sites plays the major role in this alteration of the surface hydrophilicity of such heterostructured coatings. The ratio between the surface concentrations of electrons and holes can be changed considerably by the formation of the so-called type II heterojunction between TiO 2 and ZnO, yielding an effective charge separation. The proposed approach based on the creation of these type II heterostructures seems to be promising and productive both for fundamental studies of the photoinduced surface superhydrophilicity and for the application of self-cleaning coatings with controlled wettability.

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