Introduction

Since O’Regan and Grätzel reported their breakthrough results in 1991, dye sensitized solar cells (DSSCs) as the next generation of solar cells have received tremendous interests due to their low cost and high theoretical performance1,2. In recent years, many efforts have been made to improve the performance of solar cells and an efficiency of 14.5% was reached for the liquid-based DSSCs3. A typical DSSC is composed of a dye sensitized nanocrystalline TiO2 film, an electrolyte containing I3/I redox couple, and a Pt counter electrode4. TiO2 photoanode structures play a crucial role in the charge transport and the amount of adsorbed dye molecules, which would significantly affect the overall energy conversion5,6. Therefore, intensive research has focused on the modification of working electrode with high surface area, fast electron transport pathways, and so on, which would remarkably improve the performance of DSSCs7,8,9.

In this context, many cited studies are concerned with the engineering of the photoanode interfaces in DSSCs10,11,12. As is well known, several important processes occur at TiO2/dye/electrolyte interface, such as the electrons injection from dyes to the conduction band of TiO2 and the back reaction of injected electron in nanocrystalline films with electrolyte and oxidized dyes13,14. In order to facilitate electron transport and reduce the charge recombination, several research groups have recently attempted to modify the surface of TiO2 with a thin insulating layer by forming an energy barrier between TiO2 electrodes and electrolyte15,16. For example, Palomares et al. have grown the insulating layer on nanocrystalline TiO2 semiconductor films to modulate the interfacial electron transfer in DSSCs, and the cells with a Al2O3 overlayer achieved an enhancement in ISC and VOC17. Many metal oxides with wide bandgap like MgO18, NiO19 and Nb2O520 have been developed to deposit on TiO2 film as surface passivation for the purpose of accelerating the electron transfer at interface. Among these metal oxide materials, p-type semiconductor NiO with a wide band gap (Eg = 3.55 eV) shows excellently thermal and chemical stability, which has become a promising material in photoelectrochemical devices21. The combination of p-NiO and n-TiO2 has been proven to facilitate charge separation, which in turn leads to the enhancement of the VOC and the conversion efficiency in DSSCs22. Moreover, the modification of NiO by doping with impurities such as various metal ions has been demonstrated to be an efficient approach to improve the photoelectrochemical properties23. For example, lithium as dopant to increase the carrier concentration and mobility and improve the electrical conductivity of NiO, which has been reported to be potential material for applications at gas sensor and p-type DSSCs24,25.

In this study, the composite electrodes comprising n-type TiO2 and p-type NiO:Eu3+,Tb3+ sensitized with N719 are for the first time applied to construct DSSCs. For better confirming the effect of NiO and NiO:Eu3+,Tb3+ on the performance of solar cells, the comparisons between the DSSC with the above composite working electrode and the conventional TiO2-based DSSC were also made in this paper.

Methods

Synthesis of NiO and NiO:Eu3+,Tb3+

NiO and NiO:Eu3+,Tb3+ were prepared using a sol-gel method. Typically, 0.05 M nickel acetate was dissolved into a mixing solution of 2-Methoxyethanol and Monoethanolamine under stirring at 60 °C, and the molar ratio of nickel acetate to Monoethanolamine is 1:1. Moreover, in order to synthesis NiO:Eu3+,Tb3+, Eu(NO3)3·6H2O and Tb(NO3)3·6H2O were dissolved into the above solution with a molar ratio of NiO to RE3+ being 1:0.01:0.01 under stirring. Then, NiO and NiO:Eu3+,Tb3+ sol were obtained after stirring for 1 h. In order to collect the sample powers for further analysis, the obtained sol was dried at 80 °C, followed by annealing at 500 °C for 2 h.

DSSCs assembly

Prior to the fabrication of DSSCs, fluorine doped tin oxide (FTO, transmittance = 85%) conductive glasses acted as substrates were cleaned with acetone, ethanol and deionized (DI) water, followed by drying. TiO2 sol prepared as the previous method was spin-coated on FTO to suppress the back electron transfer from FTO to electrolyte26. To prepare porous TiO2 working electrodes, the pastes were coated on substrates by the doctor blade method, followed by sintering at 450 °C for 30 min. After cooling down to room temperature, NiO and NiO:Eu3+,Tb3+ layer were deposited on the bare TiO2 electrode to form TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ composite structures by spin-coating at 3000 rpm for 30s. After annealing at 500 °C for 2 h, these samples were immersed into N719 ethanol solution for 24 h. Pt (OPV-Pt-S) counter electrode was spin-coated on FTO glass and annealed at 450 °C for 30 minutes. Subsequently, the dye-sensitized photoanodes and Pt counter electrode were fixed together using a hot-melt film spacer. Finally, a DSSC was assembled by injecting electrolyte (OPV-MPN-I) into the space between the electrodes.

Characterization and measurement

The phase structure of NiO and NiO:Eu3+,Tb3+ was characterized by X-ray diffraction (XRD) using a D8 ADVANCE with Cu Kα at λ = 0.15406 nm. X-ray photo-electron spectroscopy (XPS) was performed on a Thermo ESCALAB 250XI electron spectrometer equipped with Al Ka X-ray radiation (E = 1486.6 eV) as the source for excitation. The photoluminescence (PL) of samples was measured with Fluoromax-4 spectrometer made by HORIBA. The surface and cross-section morphology of photoanode structures were observed by field emission scanning electron microscope (FE-SEM, Quanta FEG250). The optical absorption spectra of different composite anode films and dye desorbed from photoanodes were recorded by UV-vis-NIR spectrophotometer (TU-1901). The electrochemical measurements were performed by an electrochemical analyzer in a standard three-electrode system with composite films coated-FTO as the working electrode, platinum wire as the counter electrode, Ag/AgCl electrodes as the reference electrode, and the supporting electrolyte was 0.5 M Na2SO4 aqueous solution. IV characteristics of the DSSCs were measured with an Aglient B2901A source/meter under a Xe lamp. The irradiation areas of the working electrode were 0.16 cm2. All of these measurements were carried out at room temperature.

Results and Discussion

The XRD patterns are performed to characterize the influence of rare earth ions dopant on the crystallization of NiO, as shown in Fig. 1. The observed diffraction peaks (111), (200), (220), (311) and (222) can be readily indexed to the cubic phase of NiO (JCPDS No. 44–1159). No other impurity diffraction peaks are observed, indicating that rare earth ions might incorporate into the lattice. The sharp peaks observed from XRD patterns confirm the formation of highly crystalline NiO phase. The crystallite size of the nanocrystals was calculated about 10 nm by Scherrer formula. Apparently, the crystallite size D correlated inversely with full-width half-maximum of the diffraction peak β. Thus, the size of NiO:Eu3+,Tb3+ is slightly larger than pure NiO due to the smaller β. Indeed, the incorporation of rare earth ions may lead to lattice distortion, which can be reasonably explained by the fact that the ionic radii of Eu3+ and Tb3+ is larger than that of Ni2+.

Figure 1
figure 1

XRD patterns of (a) NiO and (b) NiO:Eu3+,Tb3+.

In order to characterize the doping of Eu3+,Tb3+, the XPS measurement was conducted as shown in Fig. 2. As presented in Fig. 2(a), the Ni 2p region comprises four peaks: the main peak in Ni 2p3/2 was located at 854 eV while its satellite was detected at 862 eV, and the peaks at 872 and 879 eV corresponded to Ni 2p1/2 main peak and its satellite respectively. And Fig. 2(b) shows two peaks resulting from the lattice oxygen at 529 eV and 531 eV. The Eu 3d5/2 and Eu 3d3/2 (Fig. 2(c)) binding energy peak positions were found at 1135 eV and 1165 eV, while the broad peak at 1242 eV and 1280 eV were identified as Tb 3d (Fig. 2(d)), suggesting the presence of Eu and Tb in the sample. However, the diffraction peaks related to Eu and Tb were not observed in Fig. 1(b), it was certain that Eu and Tb ions had been successfully incorporated in NiO lattice.

Figure 2
figure 2

XPS spectra of (a) Ni 2p, (b) O 1s, (c) Eu 3d and (d) Tb 3d for NiO:Eu3+,Tb3+.

Figure 3 shows the surface and cross-section SEM images of the as-prepared photoanodes FTO/TiO2/NiO and FTO/TiO2. From the top view observation of the photoanode, both samples exhibit the uniform surface morphologies with high porosity. The thickness of the composite films is about 12 μm as shown in the cross-sectional SEM images (Fig. 3(c,d)), and a very thin NiO layer with average thickness of 50 nm directly coated on FTO was observed in the inset.

Figure 3: Surface and cross-section SEM images of FTO/TiO2 (a,c) and FTO/TiO2/NiO (b,d).
figure 3

The inserts show cross-section image of NiO coated on FTO.

The absorption spectra of TiO2, TiO2/NiO, TiO2/NiO:Eu3+,Tb3+ and dye desorbed from various photoanodes were measured. From Fig. 4(a), it can be seen that the absorption intensity of TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ is higher than that of pure TiO2, which can be ascribed to the UV-light absorption of rare earth ions and the slightly increasing thickness of composite films. Furthermore, the presence of doped Eu3+ and Tb3+ can create an impurity energy level, causing the absorption spectra shifted to lower energy region. Therefore, the absorption could be significantly enhanced in 400 nm–600 nm region as shown in Fig. 4(a), extending the photoresponse to visible light for DSSCs. In order to measure the dye loading amount of different samples, the absorption spectra of dye desorbed from various photoanodes in NaOH solution was investigated according to the previous literature7. Typically, the different photoanodes sensitized by dye were immersed in NaOH solution for several minutes, then the N719 can be desorbed from photoanode and dissolved into the NaOH solution. As can be seen in Fig. 4(b), the absorption spectra of dye desorbed from TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ films was similarly, which were all lower than raw TiO2 film due to the reduced surface area of photoanodes.

Figure 4
figure 4

Absorption spectra of (a) TiO2, TiO2/NiO, TiO2/NiO:Eu3+,Tb3+ and (b) dye desorbed from different photoanodes.

To study the separation efficiency of photogenerated electrons and holes, the room temperature PL spectra of the as-synthesized composite structure TiO2, TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ were carried out, respectively. Figure 5 exhibits the PL spectra of all samples excited at 300 nm. It is obvious that the PL intensity follows the sequence of TiO2>TiO2/NiO>TiO2/NiO:Eu3+,Tb3+. The decrease of PL intensity indicates the efficient electron-hole separation and long-lived carriers. In this study, depositing a thin NiO layer on TiO2 could form a p-n junction, which facilitates the charge separation. In addition, rare earth ions could enter into the lattice of NiO and produce the shallow trapper, promoting the lifetime of carrier and reducing the recombination of electrons and holes effectively. Therefore, it is conclusion that the presence of NiO:Eu3+,Tb3+ could be effective to enhance the photovoltaic performance of DSSCs.

Figure 5
figure 5

PL spectra of TiO2, TiO2/NiO and TiO2/NiO:Eu3+,Tb3+.

The effect of dopants on NiO was investigated and discussed. Firstly, according to the results of XRD and XPS measurements for NiO:Eu3+,Tb3+, it was certain that Eu and Tb ions had been successfully incorporated in NiO. The Mott-Schottky (MS) measurement for NiO and NiO:Eu3+,Tb3+ film was also conducted. As shown in Fig. 6, the curves show negative slopes, consisting with p-type semiconductor. According to the equation 1/C2 = (2/qεε0ND )(E − EFB − kT/q), where C is capacitance of the space charge region, ε is dielectric constant of the semiconductor, ε0 is permittivity of free space, ND is donor density, E is applied potential, and EFB is flatband potential. The charge carrier concentration ND is negative correlated with the slopes, and the smaller slope of NiO:Eu3+,Tb3+ corresponds to higher carrier concentration than NiO. The increased carrier concentration of Eu3+,Tb3+ doped NiO will exhibit better electrical conductivity, leading to easier electron transfer from dye to TiO2 and excellent performance of DSSCs.

Figure 6
figure 6

MS plots of (a) NiO and (b) NiO:Eu3+,Tb3+ in 0.5 M Na2SO4 electrolyte.

To understand the reasons caused an enhancement of charge separation efficiency for the solar cell with a thin barrier layer, the flat band potential EFB of different three composite films were also evaluated by MS measurement. Figure 7 displays the MS plots of TiO2, TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ respectively, and all the samples show positive slopes, consisting with the expected n-type semiconductor characteristics. According to the above equation 1/C2 = (2/qεε0ND )(E − EFB − kT/q), EFB is determined by extrapolating 1/C2 to 0. It is clearly observed the negative shift of flat-band of TiO2/NiO:Eu3+,Tb3+ compared to that of TiO2 and TiO2/NiO in Fig. 6, which suggests the increase of electron concentration and more positive Fermi levels EF. In addition, the NiO:Eu3+,Tb3+-coated TiO2 layer exhibits a smaller slope than other samples, indicating an increased carrier densities in TiO2, thus the JSC values of solar cells could be probably increased. Moreover, the generated voltage in DSSCs corresponds to the difference between the Fermi level of the mesoporous semiconductor and the redox potential of the electrolyte27. Therefore, the energy gap between TiO2 Fermi level and redox potential will be enlarged with the elevated EF, contributing to a higher VOC value in DSSCs.

Figure 7
figure 7

MS plots of (a) TiO2, (b) TiO2/NiO and (c) TiO2/NiO:Eu3+,Tb3+ in 0.5 M Na2SO4 electrolyte.

The electron collection efficiency and charge recombination at TiO2/electrolyte interface was analyzed by the open-circuit voltage decay, which monitors the photovoltage decay of devices through interrupting a steady-state illumination28. Under constant illumination, the free electron concentration n increases with the concentration n0 in the dark. The open circuit voltage of solar cell is determined by the equation VOC = (EF − E0 )/e = KBT/e ln(n/no ). thus there was a positive correlation between Voc and electron concentration n. As shown in Fig. 8, the photovoltage keeps a constant value under illumination with the order of TiO2/NiO:Eu3+,Tb3+>TiO2/NiO>TiO2 for DSSCs, suggesting an increased free electron concentration in TiO2/NiO:Eu3+,Tb3+ and TiO2/NiO composite structures. A subsequent decay process of voltage occurs via interrupting the steady-state illumination, in which the free electron density in the semiconductor transforms from the initial steady state to the dark equilibrium, indicating the recombination process of electrons in the conduction band of TiO2 with the electrolyte. The slow decay responses of TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ composite structures indicates that the introduction of NiO and NiO:Eu3+,Tb3+ could decrease the interfacial charge recombination compared to the pure TiO2 film. In addition, the electron lifetime is given by the equation τ = −KBT/e (dVOC/dt)−1. thus the smaller slope during the decay process indicating the longer electron lifetime. The longer lifetime for TiO2/NiO:Eu3+,Tb3+ based DSSCs is due to the presence of barrier layer, which could reduce the back-transfer of electron from TiO2 to electrolyte.

Figure 8
figure 8

Decay results of VOC for the bare and barrier-layer coated DSSCs.

Electrochemical impedance spectroscopy (EIS) technique had been widely employed to investigate internal resistance and charge transfer process in DSSCs29. As shown in Fig. 9, the Nyquist diagrams of solar cells with three different photoelectrodes under illumination exhibit two semicircles, corresponding to the electron transfer at the dye-sensitized photoelectrode/electrolyte interface and Pt/electrolyte interface resistance, respectively. The larger the radius of the middle frequency semicircle is in the Nyquist plots, the higher charge transfer resistance at TiO2/dye/electrolyte achieves. Apparently, in middle frequency, bare TiO2-based solar cell possesses a larger radius than the devices assembled with TiO2 film coated by NiO and NiO: Eu3+,Tb3+. The decrease in the radius reveals the lower interface resistance, which is mainly attributed to the reduction of direct exposure area of TiO2 to the electrolyte with the presence of passivation layer. Meanwhile, the conductivity of semiconductor was improved by doping RE3+ ions, resulting in accelerating electron transfer at the interface. Therefore, the solar cells assembled with NiO: Eu3+,Tb3+ exhibit lower interface resistance, so as to achieve a faster interfacial electron transport and higher photoelectric performance.

Figure 9
figure 9

Impedance spectra of the devices with TiO2, TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ under illumination.

The influence of NiO and NiO:Eu3+,Tb3+ on I-V characteristics of DSSCs was also investigated. Figure 10 shows I-V curves of the DSSCs based on TiO2, TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ electrodes under illumination respectively, and Table 1 presents corresponding photovoltaic parameters of solar cells. The typical DSSC using pure TiO2 shows short circuit current density (JSC) of 13.15 mA cm−2, open circuit voltage (VOC) of 0.74 V, fill factor (FF) of 0.63, and power conversion efficiency (PCE) of 6.17%, which are lower than that of devices with NiO or NiO:Eu3+,Tb3+ layer. The charge recombination between TiO2 and electrolyte leads to the decreased performance of solar cells to a large extent. When depositing a thin NiO layer, the performance has improved remarkably, showing a JSC of 16.18 mA cm−2, and a VOC of 0.77 V, yielding 7.81% conversion efficiency. The enhancement is ascribed to the presence of barrier at the interface between TiO2 film and electrolyte. As the previous reports, an insulate oxide layer coated on nanoporous films acted as a barrier for charge recombination can induce the improvement in ISC and VOC30. Similarly, the function of NiO could be explained act as a barrier layer for charge recombination between electrolyte and the electrons in the TiO2 conduction band, which can be confirmed by the results of open-circuit voltage decay. The cell efficiency could be effectively improved by retarding the recombination. Moreover, p-type semiconductor NiO integrated with n-type semiconductor TiO2 could form a p-n junction, which facilitates the charge separation. In addition, Eu3+,Tb3+ co-doped NiO with higher conductivity could further suppress the recombination of carriers by accelerating the interfacial electron transfer through the above analysis. It is clear that an optimal photovoltaic performance with JSC = 17.4 mA cm−2, VOC = 0.78 V, and η = 8.8% was achieved by the introduction of NiO:Eu3+,Tb3+ in cells. At the same time, an obvious increase in VOC was obtained due to the retarded back-reaction of injected electron transfer at TiO2/dye/electrolyte interface.

Figure 10
figure 10

I-V curves of the DSSCs made from TiO2, TiO2/NiO and NiO:Eu3+,Tb3+ electrodes.

Table 1 Photovoltaic parameters of DSSCs based on TiO2, TiO2/NiO and NiO:Eu3+,Tb3+ electrodes.

The schematic diagrams of the electron transfer path in the dye-sensitized photoanodes were depicted in Fig. 11. For the conventional DSSCs, the excited electrons were directly transferred from dye to the conduction band (CB) of TiO2. When depositing a thin NiO or NiO:Eu3+,Tb3+ layer on TiO2 nanocrystalline films, the dye can adhere to the surface of TiO2 or NiO particles. According to the potential level, the excited electrons of the dye adsorbed on NiO cannot be injected into the CB of NiO because the dye excited level is below than the CB potential level of NiO. However, another electron transfer path is possible that the photo-induced electrons may transfer to the CB of TiO2 via tunneling through NiO layer. NiO and NiO:Eu3+,Tb3+ layer could act as a barrier layer for charge recombination between the electrons in the CB of TiO2 and the oxided dye or electrolyte and a p-n junction was formed between TiO2 and NiO or NiO:Eu3+,Tb3+, which would facilitate the charge separation. Moreover, Eu3+,Tb3+ doped NiO increased carrier concentration and electrical conductivity, leading to easier electron transfer at TiO2/dye/electrolyte interface in DSSCs.

Figure 11
figure 11

The schematic diagrams of DSSCs.

Conclusions

Eu3+, Tb3+ co-doped and undoped NiO films were deposited on TiO2 constructing photoanode of DSSCs and an efficient enhancement in photovoltaic performance for cells was obtained. In this study, the function of a thin NiO:Eu3+,Tb3+ layer on TiO2 particles were summarized: (a) it acted as a barrier for the recombination of electrons in CB of TiO2 and the oxidized dye/electrolyte interface; (b) the n-p junction that formed between TiO2 and NiO could facilitate the electron transfer from NiO to TiO2; (c) the introduction of rare earth ions could further increase carrier concentration and improve the electron transport in solar cells. Therefore, the composite electrode TiO2/NiO and TiO2/NiO:Eu3+,Tb3+ is a promising method to modify photoanode of DSSCs with excellent solar-to-electric efficiency.

Additional Information

How to cite this article: Yao, N. et al. Reduced interfacial recombination in dye-sensitized solar cells assisted with NiO:Eu3+,Tb3+ coated TiO2 film. Sci. Rep. 6, 31123; doi: 10.1038/srep31123 (2016).