Initiation and Growth of Self-Organized TiO[sub 2] Nanotubes Anodically Formed in NH[sub 4]F∕(NH[sub 4])[sub 2]SO[sub 4] Electrolytes

Taveira, Luciano; Macák, Jan M.; Tsuchiya, Hiroaki; Dick, Luís Frederico Pinheiro; Schmuki, Patrik

doi:10.1149/1.2008980

Cited by 305 publications

(224 citation statements)

References 48 publications

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“…In Figure 5, the value of j from the lowest to the highest are on the CG30-4000, CG30-800 and CG30-14000 samples, respectively, therefore their δ b after Stage I will decrease in that order. The value of t c at the top of TNT layers after the anodization process, also supports this relation (Figure 9), because this capping oxide layer seen at this stage is the penetrated compact oxide layer formed in Stage I [24], therefore the value of t c shows the value of δ b when TNTs started nucleation.…”

Section: The Influence Of Mechanical Preparation On the Morphologies supporting

confidence: 69%

“…electrochemical parameters such as potential [18], electrolyte types [19][20][21][22], water content [23] and sweep rates [24]. However, the influence of intrinsic factors, such as surface roughness, surface conditions and grain size and orientation of the titanium substrate are rarely studied [25][26][27][28] and the significant influence of sample preparation methods on TNT growth makes it difficult to study the effects of grain size separately [27,28].…”

Section: Introductionmentioning

confidence: 99%

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The influence of surface roughness and high pressure torsion on the growth of anodic titania nanotubes on pure titanium

Gao

Starink

2016

Applied Surface Science

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Anodic titanium dioxide nanotube (TNT) arrays have wide applications in photocatalytic, catalysis, electronics, solar cells and biomedical implants. When TNT coatings are combined with severe plastic deformation (SPD), metal processing techniques which efficiently improve the strength of metals, a new generation of biomedical implant is made possible with both improved bulk and surface properties. This work investigated the effect of processing by high pressure torsion (HPT) and different mechanical preparations on the substrate and subsequently on the morphology of TNT layers. HPT processing was applied to refine the grain size of commercially pure titanium samples and substantially improved their strength and hardness. Subsequent anodization at 30 V in 0.25 wt. % NH 4 F for 2 hours to form TNT layers on sample surfaces prepared with different mechanical preparation methods was carried out. It appeared that the local roughness of the titanium surface on a microscopic level affected the TNT morphology more than the macroscopic surface roughness. For HPTprocessed sample, the substrate has to be pre-treated by a mechanical preparation finer than 4000 grit for HPT to have a significant influence on TNTs. During the formation of TNT layers the oxide dissolution rate was increased for the ultrafine-grained microstructure formed due to HPT processing.

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Section: The Influence Of Mechanical Preparation On the Morphologies supporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

The influence of surface roughness and high pressure torsion on the growth of anodic titania nanotubes on pure titanium

Gao

Starink

2016

Applied Surface Science

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“…These layers have a limited thickness about 500-600 nm. By taking into account the importance of the pH gradient within the tube 7 , and using buffered neutral electrolytes that containing NaF or NH4F instead of HF, the thickness of the self-organized nanotube titanium oxide layers will increase more than 2 micrometer [61][62][63][64] . The third generation of the nanotubes were grown in (almost) water free electrolytes.…”

Section: Importance Of Titanium Oxide Nanostructurementioning

confidence: 99%

The Electrochemical Behavior of Titanium Improved by Nanotubular Oxide Formed by Anodization for Biomaterial Applications: A Review

Al-Swayih¹

2016

Orient. J. Chem

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Titanium oxide nanotube is gaining prominence in many applications like solar energy, sensors, catalyst and biomaterials. In this paper, we briefly review the electrochemical behavior of titanium oxide nanotube prepared by anodization in simulated body fluids. The electrochemical behavior of TiO 2 nanotube depends on its morphology and surface properties. When titanium oxide nanotube formed by anodization, these surface properties are depending strongly on two factors, the parameters of anodization process and the conditions of employed electrolyte. These factors must be chosen in correct manner to optimized titanium oxide nanotube with desired properties for specific application.

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“…Recently, we have shown that the tubes can be grown to a length of several micrometers, giving an aspect ratio of a few hundreds. [15][16][17][18][19] This can be achieved by tailored anodization in neutral solutions containing NH 4 F 15-17 or NaF 18 or in glycerol/NH 4 F mixtures. 19 We have already used the nanotubular structures to dye-sensitize them in the visible light 4 or as a catalyst support for methanol electrochemical oxidation, 20 and we have shown how to use ion implantation 21,22 and thermal treatment to N-dope the tubes.…”

mentioning

confidence: 99%

Photoelectrochemical properties of N-doped self-organized titania nanotube layers with different thicknesses

et al. 2006

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The present work reports nitrogen doping of self-organized TiO 2 nanotubular layers. Different thicknesses of the nanotubular layer architecture were formed by electrochemical anodization of Ti in different fluoride-containing electrolytes; tube lengths were 500 nm, 2.5 m, and 6.1 m. As-formed nanotube layers were annealed to an anatase structure and treated in ammonia environment at 550°C to achieve nitrogen doping. The crystal structure, morphology, composition and photoresponse of the N-doped were characterized by scanning electron microscopy, x-ray diffraction, x-ray photoelectron spectroscopy, and photoelectrochemical measurements. Results clearly show that successful N-doping of the TiO 2 nanotubular layers can be achieved upon ammonia treatment. The magnitude of the photoresponse in ultraviolet and visible light is strongly dependent on the thicknesses of the layers. This effect is ascribed to recombination effects along the tube length.

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Initiation and Growth of Self-Organized TiO[sub 2] Nanotubes Anodically Formed in NH[sub 4]F∕(NH[sub 4])[sub 2]SO[sub 4] Electrolytes

Cited by 305 publications

References 48 publications

The influence of surface roughness and high pressure torsion on the growth of anodic titania nanotubes on pure titanium

The influence of surface roughness and high pressure torsion on the growth of anodic titania nanotubes on pure titanium

The Electrochemical Behavior of Titanium Improved by Nanotubular Oxide Formed by Anodization for Biomaterial Applications: A Review

Photoelectrochemical properties of N-doped self-organized titania nanotube layers with different thicknesses

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