Abstract
Titanium dioxide thin films were deposited on crystalline silicon substrates by electron beam physical vapor deposition. The deposition was performed under vacuum ranging from 10−5to 10−6Torr without process gases, resulting in homogeneousTiO2-xlayers with a thickness of around 100 nm. Samples were then annealed at high temperatures ranging from500°C to800°C for 4 hours under nitrogen, and their structural and optical properties along with their chemical structure were characterized before and after annealing. The chemical and structural characterization revealed a substoichiometricTiO2-xfilm with oxygen vacancies, voids, and an interface oxide layer. It was found from X-ray diffraction that the deposited films were amorphous and crystallization to anatase phase occurred for annealed samples and was more pronounced for annealing temperatures above700°C. The refractive index obtained through spectroscopic ellipsometry ranged between 2.09 and 2.37 in the wavelength range, 900 nm to 400 nm for the as-deposited sample, and jumped to the range between 2.23 and 2.65 for samples annealed at800°C. The minimum surface reflectance changed from around 0.6% for the as-deposited samples to 2.5% for the samples annealed at800°C.
Highlights
Titanium dioxide (TiO2) has promising physical, chemical, and optical properties that make it an interesting material for a wide range of applications
The main observation from the X-ray photoelectron spectroscopy (XPS) results is that the titanium spectra represent a single Ti4+ peak at a binding energy that corresponds to its bonding with oxygen within the TiO2−x structure, where the Ti4+ oxidation state remains unchanged for all samples annealed up to 800∘C
(4) TiO2−x films deposited by e-beam assisted physical vapor deposition (PVD) without introducing a process gas and without ionbeam assistance on c-Si substrates exhibit slow crystallization on the surface of the films even at high annealing temperatures
Summary
Titanium dioxide (TiO2) has promising physical, chemical, and optical properties that make it an interesting material for a wide range of applications. The refractive index of the bulk crystal TiO2 ranges from 2.4 to 2.9 [2] which makes the material attractive for many optical applications including antireflective coatings for silicon based solar cells. Electron beam (e-beam) evaporation is one of the techniques used to deposit uniform and high quality titanium oxide coatings [2, 17] but still needs to be investigated explicitly due to its importance as a technique that can be used to produce antireflective coatings on an industrial scale for many applications, including solar cells. It has been reported that such TiO2 films have a degree of porosity and their refractive index is significantly lower than the bulk material [2, 5, 13]
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