Facile fabrication of superhydrophilic/superhydrophobic surface on titanium substrate by single-step anodization and fluorination

•A facile, scalable and cost-effective method to produce superhydrophilic/superhydrophobic Ti surfaces is reported.•Superhydrophilic surfaces with 0° WCA were obtained by single-step anodization process.•The superhydrophilic surfaces will become superhydrophobic after fluoroalkylsilane modification....

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Veröffentlicht in:Applied surface science 2015-05, Vol.338, p.126-136
Hauptverfasser: Liang, Junsheng, Liu, Kuanyao, Wang, Dazhi, Li, Hao, Li, Pengfei, Li, Shouzuo, Su, Shijie, Xu, Shuangchao, Luo, Ying
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Sprache:eng
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Zusammenfassung:•A facile, scalable and cost-effective method to produce superhydrophilic/superhydrophobic Ti surfaces is reported.•Superhydrophilic surfaces with 0° WCA were obtained by single-step anodization process.•The superhydrophilic surfaces will become superhydrophobic after fluoroalkylsilane modification.•Both the anodization voltage and the electrolyte temperature have great impacts on wettability of the Ti surface.•The as-prepared Ti surface show satisfactory stability in deionized water, acidic/alkaline solutions and ambient air. A facile and scalable technique for preparation of superhydrophilic/superhydrophobic titanium (Ti) surface by single-step anodization and fluorination is presented in this paper. The Ti substrates were anodized to produce micro-nano hierarchical structure which is essential for superhydrophilic surface. The water contact angles (WCAs) of 5μl water droplets on the anodized Ti surfaces were measured as low as 0°. Capillary rise measurement was used to evaluate the superhydrophilicity on Ti surfaces anodized at different conditions. Results show that higher anodization voltage can yield stronger superhydrophilicity on Ti surface, but the influence of electrolyte temperature on the superhydrophilicity has a close correlation with the anodization voltages. At 20V and 40V anodization voltages, the increase of electrolyte temperature can improve the surface superhydrophilicity, but this trend will be reversed when the voltages rise to 60V and 80V. Superhydrophobic surfaces were further obtained from fluoroalkylsilane (FAS) modification on the anodized Ti substrates. It was observed that appropriate anodization voltages and electrolyte temperatures can balance the growth and dissolution of the micro-nano hierarchical surface structure, thereby obtaining the desired superhydrophobic Ti surface. The WCA, rolling angle and contact angle hysteresis of water droplets on the best superhydrophobic Ti surface were respectively recorded as 160°, 2° and 1.7° in this work. Furthermore, the superhydrophilic and superhydrophobic Ti surfaces fabricated in this research also show satisfactory stability in acidic, neutral and alkaline aqueous solutions as well as ambient conditions.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2015.02.117