Rapid anodic oxidation of highly ordered TiO2 nanotube arrays

Wang, Yan; Wu, Yucheng; Qin, Yongqiang; Xu, Guangqing; Hu, Xiaoye; Cui, Jiewu; Zheng, Hongmei; Hong, Yongmiao; Zhang, Xinyi

doi:10.1016/j.jallcom.2011.01.096

Cited by 42 publications

(12 citation statements)

References 26 publications

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“…In addition to the vital factor of the electrolyte and voltage to the high aspect ratio of the as-prepared nanotube, anodizing time and step, fluoride concentration, and pH and temperature also have a great synergistic effect on the morphology, structure, growth rate, crystallization, and even photoelectrochemical properties of the as-prepared TNAs [8,[37][38][39][40][41][42]. For example, the transition from porous TiO 2 to a nanotubular structure is not only dependent on water content [43,44] but also depends on the anodization voltage.…”

Section: Other Factorsmentioning

confidence: 99%

Fabrication, Modification, and Emerging Applications of TiO₂Nanotube Arrays by Electrochemical Synthesis: A Review

Huang

Zhang

Lai

2013

International Journal of Photoenergy

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Titania nanotube arrays (TNAs) as a hot nanomaterial have a unique highly ordered array structure and good mechanical and chemical stability, as well as excellent anticorrosion, biocompatible, and photocatalytic performance. It has been fabricated by a facile electrochemical anodization in electrolytes containing small amounts of fluoric ions. In combination with our research work, we review the recent progress of the new research achievements of TNAs on the preparation processes, forming mechanism, and modification. In addition, we will review the potential and significant applications in the photocatalytic degradation of pollutants, solar cells, water splitting, and other aspects. Finally, the existing problems and further prospects of this renascent and rapidly developing field are also briefly addressed and discussed.

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Section: Other Factorsmentioning

confidence: 99%

Fabrication, Modification, and Emerging Applications of TiO₂Nanotube Arrays by Electrochemical Synthesis: A Review

Huang

Zhang

Lai

2013

International Journal of Photoenergy

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“…At the beginning, the small pits originated only in local regions and did not show any orderliness. With the anodization time increasing from 3 min to 7 min, the titanium oxide around the pits was continually dissolved [17]. The size of the nano-pores increased accordingly from 15 nm to 30 nm.…”

Section: Resultsmentioning

confidence: 99%

Effect of Anodization on Titanium-Porcelain Bonding

Guo

Tian

et al. 2013

Materials and Manufacturing Processes

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The effects of anodization processes on titanium-porcelain bonding were investigated. The morphologies and phase structures were evaluated by field-emission scanning electron microscopy (F-SEM) and X-ray diffraction (XRD). The bonding strength was investigated by three-point flexure test. The corrosion resistance of titanium in artificial saliva was investigated. The SEM results showed that a titanium oxide film with submicron stripes and nano-pores could be prepared by anodization and HF acid pretreatment. This titanium oxide film increased chemical bonding and mechanical interlocking between titanium and porcelain. The anodization process also enhanced the corrosion resistance of the titanium, which led to the increase of corrosion durability of the Ti-porcelain bonding strength.

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“…1. At the first step, the micro‐patterns of grooves/ridges were prepared on the cleaned Ti foils by photolithography in advance [10]; at the second step, Ti‐nanotubes were prepared on the Ti grooves of the patterned samples by the method of anodic oxidation (20 V, 2 h) [11], after the remaining photoresist was removed as above, the Ti‐nanotubes/Ti micro‐strips were obtained (labelled as P‐Ti‐nanotubes). The flat Ti foils with nanotubes (labelled as Ti‐nanotubes) and Ti foils were fabricated as a control.…”

Section: Methodsmentioning

confidence: 99%

Fabrication of micro‐patterned titanium dioxide nanotubes thin film and its biocompatibility

Xiang

Yang

et al. 2014

J. eng.

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Rapid anodic oxidation of highly ordered TiO2 nanotube arrays

Cited by 42 publications

References 26 publications

Fabrication, Modification, and Emerging Applications of TiO₂Nanotube Arrays by Electrochemical Synthesis: A Review

Fabrication, Modification, and Emerging Applications of TiO₂Nanotube Arrays by Electrochemical Synthesis: A Review

Effect of Anodization on Titanium-Porcelain Bonding

Fabrication of micro‐patterned titanium dioxide nanotubes thin film and its biocompatibility

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Rapid anodic oxidation of highly ordered TiO2 nanotube arrays

Cited by 42 publications

References 26 publications

Fabrication, Modification, and Emerging Applications of TiO2Nanotube Arrays by Electrochemical Synthesis: A Review

Fabrication, Modification, and Emerging Applications of TiO2Nanotube Arrays by Electrochemical Synthesis: A Review

Effect of Anodization on Titanium-Porcelain Bonding

Fabrication of micro‐patterned titanium dioxide nanotubes thin film and its biocompatibility

Contact Info

Product

Resources

About

Fabrication, Modification, and Emerging Applications of TiO₂Nanotube Arrays by Electrochemical Synthesis: A Review

Fabrication, Modification, and Emerging Applications of TiO₂Nanotube Arrays by Electrochemical Synthesis: A Review