Abstract
Herein we report on the synthesis and the effects of gradual loading of TiO2 nanotube array layers with ZnO upon surface wettability. Two-step preparation was chosen, where TiO2 nanotube layers, grown in a first instance by anodization of a Ti foil, were gradually loaded with controlled amounts of ZnO using the reactive RF magnetron sputtering. After crystallization annealing, the formerly amorphous TiO2 nanotubes were converted to predominantly anatase crystalline phase, as detected by XRD measurements. The as-prepared nanotubes exhibited a well-aligned columnar structure, 1.6 μm long and 88 nm in diameter, and a small concentration of oxygen vacancies. Ti2+ and Ti3+ occur along with the Ti4+ state upon sputter-cleaning the layer surfaces from contaminants. The Ti2+ and Ti3+ signals diminish with gradual ZnO loading. As demonstrated by the VB-XPS data, the ZnO loading is accompanied by a slight narrowing of the band gap of the materials. A combined effect of material modification and surface roughness was taken into consideration to explain the evolution of surface super-hydrophilicity of the materials under UV irradiation. The loading process resulted in increasing surface wettability with approx. 33%, and in a drastic extension of activation decay, which clearly points out to the effect of ZnO-TiO2 heterojunctions.
Highlights
Titanium dioxide (TiO2) is a non-toxic, chemically stable, highly active photocatalytic oxide semiconductor
Abstract: we report on the synthesis and the effects of gradual loading of TiO2 nanotube array layers with ZnO upon surface wettability
New opportunities for application of TiO2 materials occurred in different areas, such as dye-sensitized solar cells (DSSCs) and electrochemical cells, catalysis, supercapacitors [1,2,3,4,5], gas sensors [6], biomaterials [7], and environmental and energy applications [1,8]
Summary
Titanium dioxide (TiO2) is a non-toxic, chemically stable, highly active photocatalytic oxide semiconductor It can be photo-activated by UV light with energy in excess of the band gap (3.0–3.2 eV) and used for pollutant degradation in low-cost, environment-friendly applications. Large specific area is a key factor for improving the degradation rate and catalytic efficiency at the catalyst/organic pollutant interface. Nanotubes feature large area/volume ratio and faster electron transport, as well as low recombination rate of charge carriers. This enables increased photocatalytic efficiency and durability [9,10,11,12,13,14,15,16]
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