Dependence of photocatalysis on electron trapping in Ag-doped flowerlike rutile-phase TiO2 film by facile hydrothermal method

[Display omitted] •Ag doped flowerlike rutile-phase Ag-FR TiO2 film with exposed (110) and (111) facets.•The synergistic effects between (110) and (111) facets and Ag/self-doped Ti3+-oxygen.•The significance of electron trapping in photodegradation are explained in detail.•The Ag-FR TiO2 film with 1...

Full description

Saved in:
Bibliographic Details
Published inApplied surface science Vol. 534; p. 147571
Main Authors Hamed, N.K.A., Ahmad, M.K., Hairom, N.H.H., Faridah, A.B., Mamat, M.H., Mohamed, A., Suriani, A.B., Nafarizal, N., Fazli, F.I.M, Mokhtar, S.M., Omar, W.I.W., Shimomura, M.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 30.12.2020
Subjects
Ag-FR TiO2 film
facet
Hydrothermal
Photocatalysis
Rutile
Schottky barrier
Ag-FR TiO2 film
Rutile
Hydrothermal
facet
Photocatalysis
Schottky barrier
Online AccessGet full text

Cover

More Information
Summary:[Display omitted] •Ag doped flowerlike rutile-phase Ag-FR TiO2 film with exposed (110) and (111) facets.•The synergistic effects between (110) and (111) facets and Ag/self-doped Ti3+-oxygen.•The significance of electron trapping in photodegradation are explained in detail.•The Ag-FR TiO2 film with 1 wt% Ag showed the best performance of methylene blue degradation. Ag-doped flowerlike rutile-phase (Ag-FR) TiO2 film with exposed (110) and (111) facet was fabricated by a facile hydrothermal method at 150 °C without additive or capping agent with different Ag content ranging from 0.5 to 2 wt%. This study investigated the influence of Ag content in enhancing the photocatalytic activity of Ag-FR TiO2 film. The flowerlike structures increased the active area of the TiO2 film. XPS revealed that the concentration of Ti3+-oxygen vacancy defects increased upon doping, while TEM revealed that the (110) and (111) are highly exposed facets of rods with flowerlike structure. The effectiveness of the Ag-FR TiO2 film was tested on methylene blue degradation under xenon lamp irradiation. The Ag-FR TiO2 film with 1 wt% Ag resulted in the highest methylene blue degradation, which was 20% higher than degradation by the undoped TiO2. The synergistic effect between both (110) and (111) facets and Ti3+-oxygen vacancy from Ag play an important role in reducing the band gap and acts as an electron trap. This suppresses recombination between electrons and holes to enhance the photocatalytic activity thus extending the lifetime of the photogenerated electron and hole.
ISSN:0169-4332
DOI:10.1016/j.apsusc.2020.147571