Characterization and Photocatalytic Activity of TiO 2 Nanotube Films Prepared by Anodization

Titanium dioxide nanotube (TNT) arrays were prepared in electrolytes containing fluoride by anodic oxidation. Different preparation parameters were investigated in order to evaluate their effects on length and inner diameter of nanotube, including weight ratio of glycerol to water, anodization voltage, electrolysis time, bath temperature, and electrolyte solution pH. The well defined and highly ordered TNT arrays were formed in electrolyte containing 40, and 20% water. The inner diameter of TNT was observed to increase as anodization voltage increased across the range of 10–40V. The length of TNT was affected simultaneously by both anodization voltage and electrolysis time. The inner diameter and length depend on bath temperature below 60C. The morphology of TNT was well defined and highly ordered only at electrolyte solution pH of 6 across the pH range of 2–10. Photocatalysis of methylene blue showed that reaction rate constants by TNT films were higher than P-25 films at comparable thickness. Reaction rate constants by TNT films increased as film thickness increased, but the enhancement was retarded when the length of TNT reached 2200 nm which appeared to be the limited penetration of incident UV light.


Introduction
In the past decade, considerable attention has been focused on using nanocrystalline TiO 2 as a photocatalyst for the degradation of organic pollutants [1].The photocatalyst titanium dioxide is a wide bandgap semiconductor, corresponding to radiation in the near-UV range.An electron-hole pair formation occurs within the conduction and valence bands of TiO 2 after the absorption of UV radiation.The positive hole is apparently able to oxidize a water molecule to hydroxyl radical [2].The hydroxyl radical, in turn, is a powerful oxidant.The oxidation of organic contaminants seems to be mediated by a series of reactions initiated by hydroxyl radical on the TiO 2 surface.However, recombination of the separated electron and hole can occur either in the volume or on the surface of the semiconductor particle accompanied with heat releasing [3].
Highly ordered TiO 2 nanotube (TNT) arrays have been regarded as potential superior photocatalyst due to their valuable high surface area structure.The one-dimensional nanostructures with tubular symmetries possessed low recombination of light-induced electron-hole pairs and high photocurrent conversion efficiency [4].Quan et al. [5], and Wang et al. [6] indicated that TNT attached to the parent titanium substrate improved the transport of the photoinduced electrons from photoanode to cathode and enhanced the photocatalytic activity of TNT.
In recent years, numerous researchers have paid their attention on developing new techniques for fabrication of TNT, such as template [7], hydrothermal [8] and anodic oxidation method [9].The electrochemical oxidization and chemical dissolution rates of TiO 2 were the keys to fabricate TNT by anodic oxidation method.The thin layer of TiO 2 was formed on the titanium surface in the onset of anodization.The pores could be observed on the surface of TiO 2 layer after the localized dissolution of the TiO 2 by fluoride ions.When the pores became deeper, the electric field at the bottom of pores was increased to enhance the electrochemical oxidization and chemical dissolution rates of TiO 2 and to form the tubular structure of TiO 2 .The length International Journal of Photoenergy of TNT remained constant when electrochemical oxidization rate and chemical dissolution rate reached dynamic balance [10].
Although various studies on the preparation of TNT had been reported, this study widely investigated the effects of various preparation parameters on length and inner diameter of TNT.These parameters included weight ratio of glycerol to water, anodization voltage, electrolysis time, bath temperature, and electrolyte solution pH.Photocatalytic efficiency was affected by diameter and length of TNT.Alivov and Fan [11] reported on the performance of dye sensitized solar cells (DSSCs) based on different diameters of TNT filled with TiO 2 nanoparticles.It is shown that the efficiency of DSSCs significantly increased with relative increasing of diameter of TNT.Macák et al. [4] revealed that higher lightinduced photocurrent can be achieved by TNT with longer tube length.
As to our knowledge there was comparatively little research on the preparation parameter of electrolyte solution pH and the comparison of photocatalysis efficiency among comparable thickness of TNT films and P-25 films.In order to examine the relation between photocatalysis rate and the length of TNT film, photocatalytic reactions of methylene blue with various thicknesses of TNT and P-25 films were also performed.

Preparation and Characterization of TiO 2 Nanotube
Arrays.A 25 × 15 mm Ti foil (99.53%) was subsequently immersed in acetone, isopropanol, methanol and deionized water for 10 minutes to remove the impurities and then dried at room temperature.Ti and Pt foils connected by Pt wire were used as anode and cathode, respectively.The glycerol solution containing 0.5 wt% NH 4 F and water content ranging from 0 to 90 wt% was used as electrolyte and transferred to an electrolytic reactor along with electrodes for the anodization of Ti foil.Anodization voltage and electrolysis time were controlled by a programmable DC power supply (CDP-350-005PB, Chyng Hong Electronic) across the range of 10-70 V and 1-8 hours, respectively.Bath temperature was controlled via a water jacket with a thermostatic circulating water bath (BL-720, Yihder Technology).Electrolyte solution pH was adjusted among 2 to 10.The complete preparation parameters are listed in Table 1.The anodized Ti foils were put into a muffle furnace at different temperatures ranged from 200 to 800 ∘ C for 3 hours to induce crystallization.Because of the TNT films calcined at 600 ∘ C presented the best photocatalytic activity (as experimental procedure described in Section 2.2), the calcination temperature of 600 ∘ C was chosen in all experiments in this study.The surface dimensions of anodized Ti foil were determined by a field-emission scanning electron microscopy (JSM-6500F, JEOL).

Photocatalytic Activity
Tests.The photocatalytic reaction system was composed of a photoreactor, UV-LED lamp, dye solution flask, peristaltic pump, and UV-Vis spectrophotometer and operated in recirculation mode.Silicone pipes connected the above equipment for circulation of the dye solution.The peristaltic pump transported methylene blue solution from the dye solution flask to photoreactor and recycled back to the dye solution flask.Major components of the photoreactor were made entirely of teflon.The photoreactor contained two hollow fillisters at the top fixture and the bottom fixture, respectively.The photocatalyst film (TNT or Degussa P-25) was attached under the top fixture.A quartz plate was mounted on the bottom fixture to penetrate the UV light.A UV-LED lamp with wavelength of 365 nm and irradiation power of 2 mW/cm 2 was put under the photoreactor.Dye solution was pumped through the flow channel hold between the top fixture and the bottom fixture.
The initial concentration of methylene blue solution was 10 mg/L for all experiments.The photocatalytic reactions were carried out with various thicknesses of TNT and P-25 films.The TNT films were prepared by anodic oxidation method, and the P-25 films were prepared by dipcoating of suspension [12].Concentrations of methylene blue were determined at the desired intervals of reaction time by a UV-Vis spectrophotometer (Spectra Academy, K-MAC).increase and high electric current densities further result in the collapse and dissolve of TNT. Figure 4(a) illustrates that the average inner diameter of TNT was ranged from 50 to 210 nm and increased almost linearly with the increasing applied anodization voltage from 10 to 40 V. Average length of TNT was also linearly increased from 608 to 2100 nm with the increasing applied anodization voltage but decreased above 30 V. Applied anodization voltage and fluoride concentration in electrolyte solution are proposed to play important roles during anodization to carry out electrochemical oxidation and chemical dissolution reactions.Lee et al. [14] recorded current-time curves during anodization with 20 V at water contents of 30 wt% in glycerol containing different amounts of NH 4 F. The current densities increased with increasing the fluoride content in the range of 0-2%.They proposed that the dissolution reaction of the anodic oxide is induced by F − ions.The growth of TNT is a result of competition between electrochemical oxide formation and chemical dissolution of oxide by fluoride ions.In this study, anodization of Ti foil was conducted in electrolyte solutions containing 0.5 wt% NH 4 F, indicating that the chemical dissolution rate of TiO 2 coating was supposed to be roughly the same for all experiments regarding to the anodization of Ti foil, while the electrochemical oxidation rate to form TiO 2 layers was varied with different applied anodization voltages.Hence, the growth of TNT was mainly determined by applied anodization voltage.Some similar results were reported in the literature.Gong et al. [9] fabricated TNT in 0.5-3.5% HF solutions by applying various anodization voltages.The length of TiO 2 nanotube was approximately 500 nm, and the average inner diameter was 25 to 65 nm.Macak et al. [15] studied the effect of anodization voltage on the fabrication of TNT by anodization in water/glycerol solution (50 : 50 vol%) containing 0.27 M NH 4 F. The authors indicated that the inner diameter was linearly increased with increasing anodization voltage.The length of TNT fabricated with anodization voltage less than 20 V was found to be increased with anodization voltage and then gradually approached to a constant value with continuously increasing anodization voltage.The experimental results are consistent with Cai et al. [16].With the application of anodization voltage higher than 30 V, the length of TNT was rapidly enhanced with growth rate greater than 300 nm/hour for anodization time less than 4 hours, and thereafter growth rate was decreased drastically to less than 60 nm/hour.For experiments conducted with lower anodization voltages, the length of TNT was gradually increased at steady growth rate of about 40 nm/hour even for anodization time of 12 hours.Normally, the decrease of tube length after a long time of electrolysis in our study (Figure 4 and remained constant thereafter.Macak and Schmuki [18] and Kim et al. [19] examined the effect of anodization time on the dimension of TNT and revealed that the tube diameter and wall thickness were not varied with anodization time.and found that TNT can still be fabricated at 35 ∘ C; however, the tube length decreases whereas tube diameter increases with elevated temperature from 10 to 35 ∘ C. Some different results were reported by various studies.Macak and Schmuki [18] anodized Ti in mixture of glycerol and water (50 : 50) containing 0.5 wt% NH 4 F at various bath temperatures of 20, 40, 60, and 80 ∘ C with 20 V for 6 hours.Their result showed that the length of TNT increased as bath temperature increased.

Effect of Electrolysis Time
There are some differences between the literature and our study including electrolyte composition, anodization voltage, and electrolysis time, and therefore the results of these studies are different.It appears that TNT could form at low bath temperature for a longer electrolysis time, but our study performs 2 hours of electrolysis time and only gets a random oxide layer.On other hands, our result is consistent with the study of Mor et al. [21].They studied the TNT prepared at different bath temperatures by 10 V anodization in an electrolyte of 0.5% HF and acetic acid mixed in a 7 : 1 ratio.The result shows that the length of the nanotubes increases from 120 nm to 224 nm with decreasing bath temperature from 50 of anodization bath will increase with rising bath temperature.At the same time, the electric field formed in titanium anode will also increase.High electric current density and appropriate chemical etching will match up and make a fast transform of oxidize layer to nanotubes at the initial oxidizing stage.The nanotubes formed in this situation got a bigger diameter and a longer length.rate and chemical etching rate of oxidizing layer.It will further control the surface morphology of TiO 2 film and whether TNT will be formed or not.

Effect of Electrolyte Solution pH.
At too low pH, chemical etching rate of fluorine ion was too big.Drastic chemical etching on surface resulted in a deep flaky layer, and TNT was unable to be formed.As electrolyte solution pH roses gradually, oxidation and chemical etching rates reached a dynamic equilibrium and promoted the form of TNT.At too high pH, oxidation rate of titanium slowed down but the chemical etching rate slowed down even more and resulted in a concave and convex porous surface.Macák et al. [22] proposed that transition and diffusion of H + ion at low pH resulted in acidic solution accumulated in the bottom of concave.Chemical etching of the accumulated acidic solution caused a deep flaky layer.Cai et al. [16] proposed that high pH caused a low oxidation rate.It needs much time to establish the dynamic equilibrium between oxidation of titanium and chemical etching of oxide layer.

Comparison of Rate Constants for TNT Film and P-25
Film.This study compared the effect of thicknesses of TNT film and P-25 film on the photocatalysis rates of methylene blue.Figure 9 showed the photocatalytic reaction rate constants of 10 mg/L methylene blue with comparable thicknesses of TNT film and P-25 film under illumination of UV-LED in a recirculation flow system as described in Experimental section.The photocatalytic reaction rate constants with TNT film thicknesses of 1900, 2100, 2200, 2530 nm are 1.26 × 10 −3 , 1.52 × 10 −3 , 1.81 × 10 −3 , and 1.90 × 10 −3 min −1 , respectively.As lengths of TNT increased the reaction rate constants increased, but the enhancement was retarded when the length of TNT reaching 2200 nm appeared to be the limited penetration of incident UV light.The photocatalytic reaction rate with TNT film was higher than P-25 film at above the film thicknesses range.This result is similar to Macak et al. 's [23].They prepared TNT film with different tube lengths of 500, 2500, and 4500 nm to study photocatalytic reaction of methylene blue and acid orange 7. The result showed that the photocatalytic reaction ratio is better for TNT films than 2500 nm thickness of P-25 film.Furthermore, the photocatalytic reaction ratio had a positive dependence on the length of nanotubes.Wu et al. [24] studied the photoelectrocatalytic degradation of methylene blue.A reaction rate constant of 2.97 × 10 −3 min −1 was observed at a low bias level of 0.6 V.Because of the electric field enhancement, the reaction constant of photoelectrocatalysis is bigger than that of our study on photocatalysis.As shown in Figure 10, the photocatalytic reaction rate constants of different thicknesses of P-25 film ranging from 1400 to 14000 nm had no obvious variation.It could be proposed that only the top layer of particle-packed P-25 film contacts with dye solution and results in photocatalytic reaction.Other P-25 below the top layer has no contribution to photocatalysis.On other hand, because of the porous structure of TNT film, the dye solution has more opportunities to contact with TiO 2 .The porous nanotube structure causes the photocatalysis rate constants to increase as the lengths of TNT increase.

Conclusion
In summary, self-organized TNT films were synthesized using anodization method in NH 4 F containing electrolyte.The growth of TNT was mainly determined by applied anodization voltage rather than bath temperature.The inner diameter of TNT was mainly determined by the anodization voltage while the length of TNT was affected by both anodization voltage, and anodization time.With the photocatalysis of methylene blue, It was found that the best well-defined, highly ordered, and uniformed TNT film was prepared in glycerol electrolyte with water content of 40%, anodization voltage of 30 V, electrolysis time of 6 hours, bath temperature of 40 ∘ C, and electrolyte solution pH of 6.The photocatalytic reaction rate constants with TNT film thicknesses ranged from 1900
Figure 2  illustrates SEM images for the influence of applied anodization voltage on the fabrication of TiO 2 nanotube arrays.These samples were prepared at water contents of 40 wt% in glycerol containing 0.5 wt% NH 4 F, anodization voltage ranged from 10-70 V, electrolysis time of 2 hours, electrolyte solution pH of 6, and bath temperature of 40 ∘ C. The TNT structure was observed at applied anodization voltage of 10-40 V but disappeared above 50 V.As shown in Figures2 and 3, Inner diameter and length of TNT prepared with applied anodization voltage of 10-40 V were determined by SEM cross-section images.

Figure 4 :
Figure 4: Dimensional control of titanium dioxide nanotube arrays with different preparation parameters of (a) anodization voltage, (b) electrocatalysis times, and (c) bath temperature.

Figure 8 1 )Figure 9 :
Figure 9: Photocatalytic reaction rate constants of TiO 2 nanotube arrays film and P-25 film as a function of film thickness.

1 )Figure 10 :
Figure 10: Photocatalytic reaction rate constants of different thicknesses of P-25 film ranged from 1400 to 14000 nm.

Table 1 :
Experimental design matrix for preparation of TNT.