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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 47, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Angelo Chianese, Luca Di Palma, Elisabetta Petrucci, Marco Stoller
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-38-9; ISSN 2283-9216 

Synthesis of Nanostructured Materials for 
Photoelectrochemical Oxidation of Organic Compounds 

Laura Mais*a, Pablo Ampudiaa, Simonetta Palmasa, Annalisa Vaccaa, Michele 
Masciaa, Francesca Ferrarab 
a
 Dipartimento di Ingegneria Meccanica, Chimica e dei Materiali, Università degli Studi di Cagliari, via Marengo 2, 09123 

Cagliari, Italy  
b
 Sotacarbo S.p.A., c/o Grande Miniera di Serbariu, 09013 Carbonia, Italy  

l.mais@dimcm.unica.it 

The present work relates to the use of titanium dioxide nanotubular array (NT) as photoanode for the 
photoelectrochemical oxidation of phenol used as model of organic compounds. Moreover, surface 
modification of NT structures has been carried out by deposition of tungsten oxide in order to enhance the 
response of the system toward wave lengths in the near visible range. 
Nanotubular structures were prepared by electrochemical oxidation of Ti foils in a water / organic solution with 
0.14 M of NH4F at room temperature. Tungsten oxide was electrochemically deposited on NTs structures in a 
hierarchical structure.  
The electro- and photoelectro-oxidation of phenol was studied in a typical three-electrode cell equipped with a 
quartz window. Irradiation of the photoanode was performed by a Xenon lamp (nominal power 300 W). 
Different electrochemical techniques, such as potential ramps and potential steps were adopted to investigate 
the performance of the system.  
SEM analysis was also performed to investigate on the morphology of the photoanode. Spectrophotometric 
analyses have been used to analyse the variation of the organic compound concentration. 

1. Introduction 
Nowadays, the contamination of natural and drinking water supplies and of the aquatic environment has 
become a serious environmental problem worldwide. Phenolic compounds are major pollutants of the aquatic 
environment due to their widespread use in agricultural, petrochemical, textile, paint, plastic, and pesticidal 
chemical industries. They are well known to be biorecalcitrant and to have acute toxicity with carcinogenic and 
mutagenic characters (Lathasree et al., 2004).  
Titanium dioxide (TiO2) has been widely studied as a photocatalyst (PC) for environmental applications, such 
as purification of waters and wastewaters. Actually, its favourable characteristics, such as remarkable charge 
transport properties and superior oxidation ability, long-term chemical stability, non-toxicity, inertness and low 
price, make it competitive with respect to other semiconductors (Qin et al., 2012). The TiO2 features determine 
to a great extent the efficiency and the performance of the degradation process. Under illumination, the 
photogenerated holes (free in the valence band or trapped at surface states) are responsible for oxidizing the 
organic substrates. However, the low utilization efficiency of visible light and the high recombination rate of 
photoinduced electron–hole pairs, hold back its application in water treatment. Photoelectrocatalysis (PEC) 
promotes the separation of electron–hole pairs by driving the electron transfer to an external circuit: thanks to 
the applied potential bias a significant enhance of the PC efficiency, by suppressing the recombination of 
photogenerated electrons and holes, can be achieved (Zhang et al., 2012). In PEC processes, the 
degradation rate of organic pollutants depends, to some extent, on the activity of the photoanode; therefore, 
improving its activity has become a primary research focus.  
One of the most studied approaches to increase the activity of TiO2 is compositional doping with anions or 
transition metals (Shankar et al., 2009). Another approach is coupling TiO2 with another metal oxide with 
narrower bandgap, such as WO3 (Eg=2.6 eV); this coupling approach is expected to provide a better charge 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1647027

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Mais L., Ampudia P., Palmas S., Vacca A., Mascia M., Ferrara F., 2016, Synthesis of nanostructured materials for 
photoelectrochemical oxidation of organic compounds, Chemical Engineering Transactions, 47, 157-162  DOI: 10.3303/CET1647027

157



separation, which could also increase the charge transport efficiency (Ilieva et al., 2012). After the photons are 
absorbed and electron-hole pairs (e-/h+) are created, the next process is the transport of each of the carriers to 
other phases or regions before recombination occurs. 
Various preparation methods are used to load WO3 species in TiO2 nanotubes, including hydrothermal 
synthesis (Kim et al., 2009) and sol–gel technique (Yang et al., 2010).  
The preparation of porous WO3 structures by anodization is very difficult. In fact, recent studies based on the 
optimization of the anodization parameters of W foils reported that longer anodization times yielded thicker 
porous layers, but the pore diameter increased (Reyes-Gil et al., 2013).  
Electrochemical methods have been proposed as alternative techniques for the production of semiconductor 
layers on conducting substrates, since they offer a number of advantages: simplicity of equipment, accurate 
control of layer thickness and applicability to substrates of complex shapes (Georgieva et al., 2012).  
WO3/TiO2 composite films have been prepared by Somasundaram et al. following a sequential deposition of 
WO3 and TiO2 from two separate baths containing tungsten and titanium precursor species, respectively 
(Somasundaram et al., 2006). 
In the present work we investigated the use of TiO2 nanotubes as a skeleton to develop WO3/TiO2 
nanostructures. Nanostructured WO3/TiO2 composites have been prepared following two different steps: 
anodization of Ti foils was firstly performed to obtain the TiO2 nanotubular structures (NTs), and then the 
electrodeposition of WO3 was realized on NTs using pulse potential techniques. Depending on the deposition 
time, different morphologies of the deposit were obtained and in turn, different performances were measured 
in terms of photocurrent responses at the related samples.  
Moreover, phenol has been used as sacrificial reagent, to react irreversibly with the photogenerated holes, this 
resulting in a higher quantum efficiency.   

2. Materials and methods 
2.1 Synthesis of TiO2 nanotubes 
Ti foils (0.25 mm thickness, 99.7 % metal basis, Aldrich) were used as raw materials to obtain the nanotubular 
structures by electrochemical oxidation. Prior to the electrochemical oxidation, Ti foils were degreased by 
sonication in acetone, then in isopropanol and finally in methanol; then, they were rinsed with deionized water 
and dried in a Nitrogen stream. 
The oxidation process was performed in (10%) deionized water / (90%) glycerol organic solution with 0.14 M 
of NH4F at room temperature. A potential ramp was imposed from open circuit voltage (OCV) at a fixed 
potential of 20 V with a scan rate of 100 mVs-1. The applied potential was maintained at this fixed value for 4 
h. A final annealing treatment was required in order to transform the amorphous structure into crystalline one 
and it was performed in air atmosphere at 400°C for 1 h. 

2.2 Synthesis of nanostructured WO3/TiO2 nanotubes 
The electrodeposition of tungsten oxide was performed at room temperature in a classical three-electrode cell 
in which a saturated calomel electrode (SCE) was the reference, a platinum grid was the counter electrode, 
while titania was used as working electrode. 
A receipt suggested by the literature was adopted to deposit tungsten oxide (Reyes-Gil and Robinson, 2013). 
Tipically, 25 mL of electrolytic solution, composed by 25 mM Na2WO4, 30 mM of concentrated H2O2, was 
used. pH of the solution was adjusted to 1.4 by adding nitric acid. The solution was prepared the day of the 
deposition experiments. 
Preliminary voltammetric study was performed which allowed to individuate the main reductive wave at -0.3 V 
vs. SCE. This potential value was adopted in the deposition process of tungsten oxide by potentiostatic runs. 
Pulse potential technique was used in order to obtain the tungsten oxide deposits over the nanotubular 
structures; the potential was alternately swiftly between opened circuit potential (OCV = 0.4 V) and -0.3 V. A 
serie of pulses of equal amplitude but different width was performed. Each pulse consisted of an ON-time of 1 
s during which -0.3 V was applied, and an OFF-time of 10 s during which the electrode was maintained at 
OCV. The number of pulses required to reach the final deposition time was calculated according to the ON-
time duration. The obtained WO3/TiO2 samples were annealed in air atmosphere at 400°C for 2h. 

2.3 Characterization of samples 
The surface morphology of the deposited films was investigated by high resolution Scanning Electron 
Microscope (SEM) equipped with Energy Dispersive X-Ray (EDX) detector (Zeiss, Germany). Same analysis 
allowed also to investigate on the elements present on the deposited layers. Top views of the TiO2 nanotubes 
were taken before and after WO3 eletrodeposition. 
A three-electrode cell with a quartz window equipped by a Pt-grid counter electrode and a SCE reference was 
used for all photoelectrochemical studies.  

158



The light source was a 300W Xe lamp (Lot Oriel) equipped with an IR water-filter. Depending on the runs, 
suitable optical filters were used in order to select the right wavelength of the light. The characterization of the 
samples was made using KNO3 0.1 M as electrolyte.  
Electrochemical measurements were recorded using a potentiostat-galvanostat (Amel 7050), controlled by 
Junior Assist software. Photoactivity of the samples was evaluated at the wave length of 400 nm (band width 
10 nm); photocurrent was calculated as the difference between the values recorded under irradiation and in 
the dark, respectively.  
Phenol was used as organic pollutant model and added to the supporting electrolyte in controlled amount of 
50 ppm.  
During the runs, samples of electrolyte were withdrawn and analysed for the concentration of reactant by 4-
aminoantipiryne method (ASTM 5530D) using UV spectrophotometer (Agilent Technologies Cary Series 
Spectrophotometer).  

3. Results and discussion 
TiO2 nanotubular structures were prepared by electrochemical oxidation performed in glycerol/water 
electrolyte in the presence of fluorides, as pitting agent. Previous studies carried out in our laboratory have 
shown that different morphologies of the samples can be obtained, depending on the experimental conditions 
adopted. In particular regular structures were obtained by using glycerol / water electrolyte (Palmas et al., 
2012). 
Figure 1 shows the morphology of the photoelectrode; TiO2 nanotubes (Figure 1a) are highly uniform and 
vertically oriented with a diameter of 50 nm of average size. After the electrodeposition process, WO3 tubular 
nanostructures grew on top of the TiO2 nanotubes developing also a cracked compact layer of WO3 (Figure 1b 
and Figure 1c).  
WO3/TiO2 nanomaterials show a multilayer structure, where the bottom is the TiO2 nanotube on Ti foil, the 
middle is WO3 tubular nanostructure and the top is a WO3 compact layer. WO3/TiO2 composite materials show 
the same ordered structure of TiO2 nanotubes with an external layer of WO3.  
 
Energy dispersive X-ray analysis (Figure 2) confirms that both Ti and W are present on top of the sample. At 
the moment, no indication about the specific W oxide form was obtained.  
However, a study reported by Pauporte (2002) relates on the electrodeposition WO3 film by exploiting a 
cathodic reduction of a peroxo precursor, Eq(1), which was obtained by mixing a tungsten precursor with an 
excess of hydrogen peroxide. The precursor was described as a dimer with the formula W2O11

2- with a 
peroxide ligand. The oxidation state of W was +6 and the deposition reaction was described as:  
 2 → 2 2 84  (1) 
 
On the bases of these results reported in the literature we can suppose that WO3 has been obtained on TiO2 
nanotubes in the solution contained a tungsten precursor with an excess of hydrogen peroxide. 
 

     

Figure 1: SEM images of TiO2 nanotubes prepared by anodizing a Ti Foil at 20 V (a) and TiO2/WO3 composite 
materials prepared at -0.3V for 5 minutes using a pulse potential technique (b and c). 

 

a b c 

159



 

Figure 2: EDX of TiO2/WO3 materials prepared at -0.3 V for 5 minutes using a pulse potential technique. 

 
Preliminary cyclicvoltammetric studies have been carried out in order to individuate the deposition potential of 
WO3 on TiO2 nanotube substrates. Figure 3 shows the cyclic voltammogram of TiO2 nanotube substrates in 
Na2WO4 and concentrated H2O2 solution; a reduction peak appears at -0.2 V that can be related to the 
cathodic reduction of the peroxo precursor. 
The electrodeposition test was performed using a pulse potential technique, where each pulse consisted of an 
ON-time of 1 s, during which -0.3 V was applied, and an OFF-time of 10 s, during which the electrode was 
maintained at OCV; the final deposition time was calculated according to the ON-time duration and, in this 
case, was set for 5 minutes. 
Photoelectrochemical performance of WO3/TiO2 composite materials has been investigated using them as 
photoanodes in the photoelectrochemical cell. Photocurrent response of pure TiO2 was also recorded under 
the same conditions, in order to compare the responses before and after WO3 assembling.  
The photocurrent behaviour of TiO2 and WO3/TiO2 nanotube electrodes was determined from current-potential 
curves obtained in supporting electrolyte (KNO3 (0.1 M)) and in the presence of phenol (50 ppm). 
Figure 4a shows the photocurrent densities measured in supporting electrolyte, at both TiO2 and WO3/TiO2 
nanotube electrodes as a function of the applied potential, using a filter of 400 nm.  
It is possible to observe that TiO2 nanotubes exhibit very small photocurrent densities, if compared to 
WO3/TiO2 nanotube composite-electrodes. Under this conditions only the photooxidation of water is allowed 
by the photogenerated holes, which may result in some oxidative intermediates, such as OH radicals; these 
intermediates can recombine with the photogenerated electrons, this decreasing the anodic photocurrent 
response (Nakamura and Nakato, 2004). The addition of phenol to the electrolyte can scavenge these 
oxidative intermediates, suppressing the recombination and improving the anodic photocurrent response.  
The behavior of WO3/TiO2 substrate in the presence of phenol is reported in Figure 4b. As can be seen, 
WO3/TiO2 electrode exhibits a doubling of the photocurrent density when phenol is added to the electrolyte.  

 
Figure 3: Cyclic voltammogram of TiO2 substrate in Na2WO4 (25 mM) and concentrated H2O2 (30 mM) 
solution. 

-12

-10

-8

-6

-4

-2

0

2

-1.1 -0.8 -0.5 -0.2 0.1 0.4 0.7 1

I /
 m

A 
cm

-2

Potential / V vs SCE

160



 
Figure 4: Photocurrent density measured at: a) TiO2 nanotubes (full bars) and WO3/TiO2 nanotubes (vertical 
lines bars) using KNO3 0.1 M as electrolyte and b) WO3/TiO2 nanotubes using KNO3 0.1 M with (horizontal 
lines bars) and without (vertical lines bars) phenol. 
 
The increase in photocurrent could be attributed to a rapid and irreversible consumption of the photogenerated 
holes by the organic substrate, which suppress the e-/h+ recombination at the interface. 
Figure 5 compares the catalytic and the photoelectrocatalytic (PEC) oxidation of phenol at WO3/TiO2 
substrate. All the degradation experiments have been performed for 450 min using a solution containing 50 
ppm of phenol. Photo-degradation was carried out at 0.7 V versus SCE, and 400 nm wavelength. Oxidation 
was also carried out at the same potential in the dark.  
As can be noticed, any catalytic activity was recorded at this potential value, neither any appreciable 
decreasing in the concentration can be attributed to a possible adsorption of phenol at the electrode surface, 
under these conditions.  
Under illumination, a clear decrease in the concentration is measured. Actually, the current value measured in 
this condition, in the order of 100 μAcm-2, does not account for all the decrease in concentration, indicating a 
combined effect of adsorption and reaction. The adsorption sites may be activated by the irradiation; at the 
same time, the applied positive bias can drive the photogenerated electrons through the 1D NTs channels, to 
the counter electrode; this in turn, increases the lifetime of photogenerated holes and improves the 
degradation rate of phenol.  
 

 
Figure 5: Variation of phenol concentration in PEC oxidation at 0.7 bias at 400 nm and a catalytic oxidation at 
0.7 bias at dark by a WO3/TiO2 composites. 

4. Conclusions 
A synthetic method has been proposed to create WO3/TiO2 nanotubular structures, that can be used as 
photoanodes in a photoelectrochemical cell for the degradation of organic compounds.  
The combination of WO3 with TiO2 nanotubular structures demonstrated to be effective in improving the 
photocurrent efficiency of the composite materials, if compared to TiO2 nanotubes alone.  

0

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0.3 0.5 0.7 0.9 1.1 1.3

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 μ
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a b 

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Further study has already been planned, and further experimentation will be carried out in order to optimize 
the nanostructure and verify the nature and composition of the oxides, and to improve the photogenerated 
carrier transport.  
Further investigation will also be approached on the adsorption of the organic substrate at the electrode 
surface, in order to derive information on the reaction mechanism.  
 

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