Dye solar cell (DSC) becomes an interesting photovoltaic generator as thin film solar cells. Despite their low conversion efficiency, they can be very suitable for a big number of applications. In addition to their low cost, DSCs can convert solar radiation into electricity not only with direct (specular) solar lightning, but even with diffused light source. Since the first use of colloidal TiO2 nanoparticles by O’Regan and Grätzel in 1991, scientific research in DSCs became promising [1]. Many techniques were used to deposit TiO2 film on different substrates, such as liquid phase crystal deposition [2], sol–gel [36] (large used), and hydrothermal deposition [7, 8]. Abdullah and Sorrell [9] used the electro phoretic deposition (EPD) technique to form TiO2 films with different thicknesses on a high purity titanium substrate. Manríquez and Godínez [10] studied the properties of a Ti(III)-doped TiO2 film formed by the EPD technique on optically transparent electrode. In this work, we report the structural, morphological and optical properties of TiO2 thin films deposited by the EPD technique (Figure 1) on a doped fluorine tin oxide (SnO2:F, i.e., FTO) layer. The formed film is used as a photo electrode in the DSC.

Figure 1
figure 1

Scheme of the electro phoretic deposition technique.

The EPD [912] is one of the colloid processes in ceramic production. It was discovered since two hundred years ago (1808) and patented in the USA in 1933. This technique was applied in multiple domains; ceramics, coatings, nanoscale assembly, etc [912]. It has many advantages such as the homogeneity of the formed film and its fast deposition velocity; it does not require any complex equipment and permits the deposition of thin films on different surface architectures [11] and different textures. The thickness of the film can be controlled via the applied voltage and the deposition duration [11].

In our case, TiO2 nanoparticles have a spherical shape in the suspension solution. When deposited by the EPD technique, the non violent arrangement of spherical particles of TiO2 on FTO creates void regions (inter spheres); which in turn, gives to the TiO2 film its porous structure, with a very high internal surface, which is very useful and may be crucial for the number of dye molecules that we can insert in a DSC and enhance its efficiency.

In this work, the thickness of the formed film is about several tenths of nanometers and was carried out using spectroscopic ellipsometry, as well as the refractive index, n, and the extinction coefficient, k, in the 200 to 800 nm wavelength range. The structural properties showing a polycrystalline aspect is carried out by X-Ray diffraction (XRD). Morphological investigations using atomic force microscopy (AFM) show no cracks in the film. In addition, the transmittance of the TiO2 film in the visible domain reaches 75%. After studying these properties, we fabricate a DSC on which we obtain an open circuit voltage Voc = 628 mV and a short circuit current Isc = 22.6 μA, where the surface of the cell is 3.14 cm2.


Thin TiO2 films are deposited on FTO substrates using the EPD technique (Figure 1). We used TiO2 powder from Aldrich (Sigma-Aldrich Corporation, St. Louis, MO, USA) where 99.7% of the particles have dimensions less than 25 nm. The electrolyte solution is composed of a mixture of 0.02 g of TiO2 nanopowder with 30 ml of isopropanol and 10 ml of acetone. Then, we added a solution of iodine (I2) dissolved in 5 ml of acetone and 0.5 ml of acetyl-acetone. The electrolyte was dried and ultrasonicated just before deposition. To enhance the TiO2 nanoparticles adhesion, the FTO film was first cleaned and exposed to UV-irradiation during 1 h. One of the electrodes is a transparent conductive oxide film, where we used FTO (SnO2:F). The latter was deposited on a glass substrate by the pyrolitic technique, and the second electrode is in aluminum (Al) deposited by thermal evaporation. A constant voltage of 80 V was applied between the two electrodes during 5 s. The used voltage and duration are optimized values. Hence, different biases and durations were used by studying the transmittance and the resistivity of the elaborated films. After deposition, the TiO2 film was annealed in air at 450 °C during 1 h to enhance the interconnection between nanoparticles. We notice that obtained film has a high adhesion to the FTO substrate. This may be explained by the generated bonding strength between the film and the substrate created during the UV-irradiation of the FTO substrate.

Results and discussion

Structural properties

We give in Figure 2 three measured XRD spectra. Figure 2a corresponds to the FTO film. Figure 2b is the XRD spectra of TiO2 where the black curve corresponds to the TiO2 powder and the red curve to the elaborated TiO2 film. By taking into account peaks of FTO (Figure 2a) and peaks of the TiO2 powder (red curve of Figure 2b), we notice in the XRD spectrum of the formed TiO2, three peaks corresponding to the (101), (004), and (211) directions. The peak (004) in both TiO2 powder and TiO2 film, at the same position of the (200) peak of FTO, was also observed by Radice et al. [12] and Fa-min et al. [13]. Unfortunately, we did not identify the new peak in the fabricated TiO2 film that appears near the peak (101) of the FTO layer.

Figure 2
figure 2

XRD spectra. (a) FTO film and (b) elaborated TiO 2 film using TiO 2 powder.

Morphological properties

The surface morphology was studied by means of AFM. In Figure 3, we give the AFM image of the TiO2 surface (Figure 3a), which was compared to the AFM image of FTO (Figure 3b). The estimated rough surface measurement of the TiO2 surface is about 49.8 nm. We can see in the AFM image that the surface reveals different grain sizes of the polycrystalline film, as established by XRD measurements. The sizes of TiO2 grains reach the micrometric scale (Figure 3a); however, they have smaller dimensions in the FTO film (Figure 3b). For the imaged region, AFM investigation shows that grain sizes vary from sub micrometric to micrometric dimension. In addition, in regions investigated by AFM, we notice the non compact morphology of the deposited TiO2 film and the absence of cracks. This is due to the fact that the suspension solution (Figure 1) contains TiO2 nano powder with a spherical shape, and the EPD technique permits their deposition in a porous medium. The latter property and the absence of cracks could be very beneficial for DSCs.

Figure 3
figure 3

AFM images. (a) Elaborated TiO 2 layer and (b) FTO thin film.

Ellipsometric study

To carry out the refractive index and the extinction coefficient, we use an ultraviolet–visible near-infrared (UV–vis-NIR) GES5 spectroscopic ellipsometer from Sopra (Uttar Pradesh, India). Measurements were achieved with an average value of incident angle about 60° in a wavelength range of 200 to 800 nm at ambient temperature. This choice of angle is justified by the best minimization of the noise level. After collecting all measurements, the determination of the physical parameters is based on the method of how to choose the best model that enables good fitting results of theoretical curves of cos(Δ) and tan(Ψ) to experimental ones as a function of the wavelength. In Figure 4, we give a schematic representation of the sample as considered in the theory to obtain the best fit. The sample is considered as formed by five mediums. In order to enhance the fitting results, all layers are supposedly homogenous, transparent, and isotropic to use the Bruggeman effective medium theory (EMA). As shown in Figure 4, we used following three basic mediums: medium 2 (porous TiO2: TiO2 + void), medium 4 (FTO), and medium 5 (glass). At the tow interfaces, we considered effective mediums formed by two phases of each one. Hence, between air and porous TiO2, we considered medium 1. Between medium 2 and medium 4, we consider the effective medium 3. These considerations are due to the surface roughness as obtained by AFM investigations. Utilizing the model structure given in Figure 4, we represent in Figure 5 the refractive index, n, and the extinction coefficient, k, as a function of the incident wavelength. The obtained values of n and k are very close to those in the literature [14]. In Table 1, we give the values of the films’ thicknesses obtained after fitting using the EMA theory.

Figure 4
figure 4

Schematic representation of the structural model of the sample used in the spectroscopic ellipsometer analysis.

Figure 5
figure 5

Refractive index,  n  , and extinction coefficient,  k  , of the TiO 2 film.

Table 1 Obtained thicknesses of mediums considered in Figure 4


Transmittance (T) of the film was carried out using a UV–vis-NIR spectrophotometer in the wavelength range from 250 to 2,500 nm. The transmittance of the TiO2 film is plotted in Figure 6 as well as the transmittance of the FTO film which is used for comparison. We notice a very useful transparency of the film in a large wavelength domain from 300 to 1,100 nm. Hence, the values of T reach 75% in the visible domain, which is very functional for DSC applications, since we will use it as the photo electrode. In addition, one can notice that as compared to the FTO/glass film, the transmittance is not diminished severely when we form the TiO2 film (Figure 6).

Figure 6
figure 6

Measured transmittance spectra of FTO/glass and TiO 2 /FTO/glass films vs. wavelength.

From the measured transmittance T given in Figure 6, we deduce the absorption coefficient α using the following relation [15]:

α 1 d ln 1 T

where d is the thickness of the film (Table 1) and T is its transmittance.

It is established that TiO2 has direct and indirect band gaps [6]. To determine values of these forbidden energies, we use the expression in Equation 2.

The relationship between the absorption coefficient α and the incident photon energy is given by the relation (Equation 2) as follows [16]:

α h v = A h v E g m

where A is a constant depending on the transition probability and m is equal to ½ for indirect gap and 2 for direct gap. The usual method to calculate the band gap energies is to plot α h v 1 m as a function of the incident radiation energy (hν) [17]. The absorption coefficient α as a function of the incident wavelength is plot in Figure 7. The band gap values are determined by extrapolating values of the absorption coefficient α to zero. Figures 8 and 9 are the plot of α h v 1 m vs. incident energy (hν). As represented in these figures, we found 4.14 and 3.40 eV for the direct and indirect band gap energies, respectively. These values are very close to those obtained by Janitabar et al. [6] for a TiO2 film elaborated by the sol–gel templating technique. The obtained value of the band gaps, especially for direct transition, could be due to the radius of quantum-sized particles [6].

Figure 7
figure 7

Absorption coefficient α as a function of the incident wavelength.

Figure 8
figure 8

Plot of (αhν) 2 vs. (hν) for the estimation of the direct gap energy value.

Figure 9
figure 9

Plot of (αhν) 1/2 vs. (hν) for the estimation of the indirect gap energy value.

Current–voltage characterization

After depositing and analyzing the TiO2 film, the photo electrode was immersed for 24 h in N3 dye solution. For the fabrication of the DSC, we used KI/I2 electrolyte dissolved in acetonitrile as solvent. The counter electrode is in aluminum on FTO. The surface area is 3.14 cm2. In Figure 10 we give the measured current–voltage (I-V) characteristic of the formed DSC performed at AM1.5 illumination. We obtain an open circuit voltage Voc = 628 mV and a short circuit current Isc = 22.6 μA. However, we notice that due to the fact that we used aluminum in the counter electrode instead of platinum, we observed a relatively rapid degradation on the counter electrode of the DSC as a function of time. This degradation could be at the origin of the leakage current, leading to a decrease of the shunt resistance of the cell as observed in the I-V curve for low voltage.

Figure 10
figure 10

AM1.5 current–voltage characteristic of the formed DSC.


In this paper we give the structural, morphological, and optical properties of TiO2 films which are formed using the EPD technique. By analyzing the elaborated film by means of XRD, AFM, ellipsometry, and UV–vis-NIR spectrophotometry, we established that EPD technique permits the formation of a film that could be useful for DSC application. Hence, the XRD characterization shows polycrystalline films. The AFM investigations show no cracks in the film. The spectroscopic ellipsometry analysis permits us to deduce the thickness of the TiO2 film which we found in the range of 70 to 80 nm, as well as the refractive index, n, and the extinction coefficient, k, in the 200 to 800 nm wavelength range. In addition, we found that the transmittance of the TiO2 film in the visible domain reaches 75% in a large spectral range.

From the I-V characteristic measured at AM1.5 of the formed DSC, we obtain Voc = 628 mV and Isc = 22.6 μA. Though we remark that due to the fact that we used aluminum in the counter electrode instead of platinum, we observed the degradation on the counter electrode of the DSC. This degradation might create a leakage current, leading to a decrease of the shunt resistance of the cell, as it can be observed in the I-V curve for low voltage.