Abstract
This study aims to demonstrate the feasibility of applying eight machine learning algorithms to predict the classification of the surface characteristics of titanium oxide (TiO2) nanostructures with different anodization processes. We produced a total of 100 samples, and we assessed changes in TiO2 nanostructures’ thicknesses by performing anodization. We successfully grew TiO2 films with different thicknesses by one-step anodization in ethylene glycol containing NH4F and H2O at applied voltage differences ranging from 10 V to 100 V at various anodization durations. We found that the thicknesses of TiO2 nanostructures are dependent on anodization voltages under time differences. Therefore, we tested the feasibility of applying machine learning algorithms to predict the deformation of TiO2. As the characteristics of TiO2 changed based on the different experimental conditions, we classified its surface pore structure into two categories and four groups. For the classification based on granularity, we assessed layer creation, roughness, pore creation, and pore height. We applied eight machine learning techniques to predict classification for binary and multiclass classification. For binary classification, random forest and gradient boosting algorithm had relatively high performance. However, all eight algorithms had scores higher than 0.93, which signifies high prediction on estimating the presence of pore. In contrast, decision tree and three ensemble methods had a relatively higher performance for multiclass classification, with an accuracy rate greater than 0.79. The weakest algorithm used was k-nearest neighbors for both binary and multiclass classifications. We believe that these results show that we can apply machine learning techniques to predict surface quality improvement, leading to smart manufacturing technology to better control color appearance, super-hydrophobicity, super-hydrophilicity or batter efficiency.
Highlights
Nowadays, ordered titanium dioxide (TiO2 ) nanotube arrays obtained by Ti anodization have overwhelmingly attracted scientific and technological interests because of their functional properties
We focused to fabricate nanoporous/nanotubes anodic titanium oxide layers through a one-step anodization process performed in fluoride-containing ethylene glycol at various anodization and voltages
Nanoporous anodic Ti oxide layers are fabricated by a one-step anodization process
Summary
Nowadays, ordered titanium dioxide (TiO2 ) nanotube arrays obtained by Ti anodization have overwhelmingly attracted scientific and technological interests because of their functional properties. TiO2 is considered a synthetic bone graft substitute [7,8] Considering their superior features including unique structure, high specific surface area, and quantum confinement effect, TiO2 nanotubes/nanoporous arrays are the most frequently fabricated nanostructures. Various methods such as template-assisted sol-gel synthesis, play a crucial role in the fabrication of Ti nanostructures [9,10]. By controlling anodization parameters, such as electrolyte type, electrolyte composition, pH, applied voltage and potential difference, temperature and anodization duration, nanostructures with different morphologies and characteristics can be obtained [14,15,19,20]. Combining all these parameters during anodization to observe all types of surface characteristics is costly
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