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Photocatalytic behavior of TiO2 films synthesized by microwave irradiation

Abstract

Titanium dioxide was synthesized on glass substrates from titanium (IV)isopropoxide and hydrochloride acid aqueous solutions through microwave irradiation using as seed layer either fluorine-doped crystalline tin oxide (SnO2:F) or amorphous tin oxide (a-SnOx). Three routes have been followed with distinct outcome: (i) equimolar hydrochloride acid/water proportions (1HCl:1water) resulted in nanorod arrays for both seed layers; (ii) higher water proportion (1HCl:3water) originated denser films with growth yield dependent on the seed layer employed; while (iii) higher acid proportion (3HCl:1water) hindered the formation of TiO2. X-ray diffraction (XRD) showed that the materials crystallized with the rutile structure, possibly with minute fractions of brookite and/or anatase. XRD peak inversions observed for the materials synthesized on crystalline seeds pointed to preferred crystallographic orientation. Electron diffraction showed that the especially strong XRD peak inversions observed for TiO2 grown from the 1HCl:3water solution on SnO2:F originated from a [001] fiber texture. Transmittance spectrophotometry showed that the materials with finer structure exhibited significantly higher optical band gaps. Photocatalytic activity was assessed from methylene blue degradation, with the 1HCl:3water SnO2:F material showing remarkable degradability performance, attributed to a higher exposure of (001) facets, together with stability and reusability.

Category

Academic article

Client

  • NORTEM / 197405

Language

English

Author(s)

  • Daniela Nunes
  • Ana Claudia Pimentel
  • Joana Vaz Pinto
  • Tomás R. Calmeiro
  • Suman Nandy
  • Pedro Barquinha
  • Luís Pereira
  • Patricia Almeida Carvalho
  • Elvira Fortunato
  • Rodrigo Ferrão Martins

Affiliation

  • NOVA University Lisbon
  • SINTEF Industry / Sustainable Energy Technology
  • University of Lisbon (ULisboa)

Year

2016

Published in

Catalysis Today

ISSN

0920-5861

Publisher

Elsevier

Volume

278

Page(s)

262 - 270

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