Synthesis and characterization of nanostructured TiO2 and TiO2/W thin films deposited by co-sputtering

Leandro García González,Daniel De Jesús Araujo Pérez,Salomón Ramiro Vásquez García,Nelly Flores Ramírez,Teresa Hernández Quiroz,Joaquín Villalba Guevara,Luis Zamora Peredo,Julián Hernández Torres,María Guadalupe Garnica Romo

doi:10.1590/s1517-707620180002.0401

Leandro García González, Daniel De Jesús Araujo Pérez + Show 7 more

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https://doi.org/10.1590/s1517-707620180002.0401

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Abstract

ABSTRACT Nanostructured TiO2 and TiO2/W thin films were deposited on Corning glass substrates by RF and DC magnetron co-sputtering at room temperature, using three targets of TiO, Ti and W. After deposition, samples were subjected to an annealing treatment in air at 500 °C for 3 hrs. The effect of the annealing treatment and tungsten addition to the TiO2 matrix were studied by Raman spectroscopy and X-ray diffraction. Morphology and composition was studied with field emission scanning electron microscopy and optical characterization was made with UV-Vis spectroscopy. All the obtained samples presented an amorphous TiO2 phase; however, after the annealing treatment, a crystallization process from amorphous to anatase phase occurred with gain sizes between 15.6 and 18.3 nm, additionally, a small amount of rutile was also observable. The SEM images corroborated the XRD behavior, besides it was possible to calculate the thickness of the films which was greater for the W-doped films owing the extra power of the sputtering growth, and after the samples had the thermal treatment the thickness decreased due to a more organized structure. Finally, the UV-vis transmittance analysis revealed that the transmittance is higher in heat-treated films as compared to those without any thermal treatment; also, the TiO2 thin films showed a greater transmittance than the W doped TiO2 films, reaching 91%. The lack of transmittance in the non-thermal-treated films made it impossible to compute the band gap of the films; nevertheless, for the thermal-treated films the band gap had a minimal change to the classic TiO2 bang gap value, even for the W doped sample, providing them with the benefits of the tungsten within the same TiO2 structure due to a great homogenization on the structure.

Highlights

The titanium dioxide (TiO2) is one of the most studied materials, owing its exceptional structural, optical, and electronic properties
The UV-vis transmittance analysis revealed that the transmittance is higher in heat-treated films as compared to those without any thermal treatment; the TiO2 thin films showed a greater transmittance than the W doped TiO2 films, reaching 91%
The anatase phase corresponding to the PDF 01-075-254 card and the rutile phase that corresponds to the PDF 03-065-0191 card

Summary

Introduction

The titanium dioxide (TiO2) is one of the most studied materials, owing its exceptional structural, optical, and electronic properties. The rutile phase has a bandgap of 3.10 eV [1,2], with a high refraction index [3,4] and a better chemical and thermal stability. The rutile phase has applications as optical coatings, solar energy converters or protective layers in microelectronics applications. The anatase phase shows a bandgap of 3.23 eV with a relatively low refraction index [5]. The brookite belongs to a group of minerals called hydrothermal, this means that it is formed by dissolution and precipitation processes related to the magma solidification in fissures on preexistent rocks, in the last decades the interest for these materials has been increasing due to their applications, e.g. as deodorization, protection against atmospheric agents or as residual water treatment; one characteristic of the brookite is that is photo-sensible to any kind of light, in contrast, anatase only reacts with ultraviolet light

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