COMPARATIVE STUDY OF TiO<sub>2</sub> AND ZnO APPLICATION IN HYBRID SOLAR CELLS USING COPOLYMER P3OT/P3MT

Larsson, Letícia Fernanda Gonçalves; Tractz, Gideã Taques; Maia, Guilherme Arielo Rodrigues; Alves, Guilherme José Turcatel; Rodrigues, Paulo Rogério Pinto; Cunha, Maico Taras da; Banczek, Everson do Prado

doi:10.21577/0100-4042.20170344

Abstract

Hybrid inorganic-organic solar cells are an attractive alternative energy source because of their low-cost production and ability to make use of a large amount of solar radiation available. This work aims to evaluate different solar cells composed of TiO₂ and ZnO with P3OT/P3MT copolymer. Layers of semiconductor oxides were deposited on transparent fluorine-doped tin oxide (FTO) by spin coating and adsorption in the polymer solution. X-ray diffraction (XRD), scanning electron microscopy (SEM), were used to characterize the fabricated semiconductors and curves of current density vs. potential (j-V), photochronoamperometry (j-t) and electrochemical impedance spectroscopy (EIS) were used to determine their electrical characteristics. The XRD analyses confirmed the crystalline nature of the oxide materials. SEM micrographs showed the spherical morphology of ZnO and the poorly defined agglomerate morphology of TiO₂. The electrochemical measurements proved that the best cell was produced with P3OT/P3MT copolymer and TiO₂, owing to its lower charge transfer resistance, with the following photovoltaic parameters: V_oc = 0.615 V ± 0.004, j_sc = 1.545 mA cm^-2 ± 0.240, FF = 0.637 ± 0.003, and η = 0.617% ± 0.117.

Keywords:
semiconductor; renewable energy; photocronoamperometry

INTRODUCTION

Hybrid solar cells are composed of three main materials: an organic material capable of absorbing of solar energy, a metallic semiconductor to allow for the transport of electrons, and a redox electrolyte for charge intermediation. The hybrid solar cells were initially developed in 1985 and are based on the formation of electron-hole pairs, connected to each other, generating an electric field derived from the separation of charges at the interface of the system.¹1 Freitas, J. N.; Pivrikas, A.; Nowacki, B.; Akcelrud, L. C.; Sariciftci, N. S.; Nogueira, A. F.; Synth. Met. 2010, 160, 1654.

When the incident light reach the device, electrons from the photosensitive material are ejected by the photovoltaic effect to the lowest unoccupied molecular orbital (LUMO) state and consequently to the conduction band of semiconductor.²2 Alwani, M. A. M.; Mohamad, A. B.; Ludin, N. A.; Kadum, A. A. H.; Sopian, K.; Renewable Sustainable Energy Rev. 2016, 65, 183. These electrons migrate to the external circuit because of the potential difference at the device interface until they reach the counter electrode (Pt); the polymer is regenerated via a diffusion process, thus completing the charge injection cycle and causing current to flow.³3 Yun, S.; Freitas, J. N.; Nogueira, A. F.; Wang, Y.; Ahmade, S.; Wang, Z-S.; Prog. Polym. Sci. 2015, 59, 1.

Semiconductor oxides such as TiO₂, ZnO, Nb₂O₅, and CeO₂ are used in these devices because they possess good photochemical properties, thermodynamic stability, great crystallinity a form transparent films invisible light and presents band gap in the order of 3 to 3.4 eV.⁴4 Vitoreti, A. B. F.; Vaz, R.; Pena, A. L.; Raphael, E.; Ferrari, J. L.; Schiavon, M. A.; Rev. Virtual Quim. 2017, 9, 4.^,⁵5 Shoaee, S.; Briscoe, J.; Durrant, J. R.; Dunn, S.; Adv. Mater. 2014, 26, 263. They are often used in combination with photosensitizing materials because it is necessary to take advantage of some effective interactions between both materials.⁵5 Shoaee, S.; Briscoe, J.; Durrant, J. R.; Dunn, S.; Adv. Mater. 2014, 26, 263.

Poly (3-alkylthiophenes) (P3ATs) are organic polymers with conjugated structures, which make them conductive and luminescent. They are considered promising alternative sensitizer materials for solar cells and in organic electronics, because they are highly flexible, are easy to produce, have low processing costs, have high mobility and are efficient charge generators (0.1 cm² V^-1 s^-1).¹1 Freitas, J. N.; Pivrikas, A.; Nowacki, B.; Akcelrud, L. C.; Sariciftci, N. S.; Nogueira, A. F.; Synth. Met. 2010, 160, 1654.

P3ATs can be obtained from the monomers of 3-octylthiophene (3OT) and 3-methylthiophene (3-MT) and are characterized by the presence of a thiophene ring containing a methyl or an octyl radical attached to the carbon at position 3 of ring 9, as shown in Figure 1.⁶6 De Santana, H.; Maia, E. C. R.; Bento, D. C.; Cervantes, T. N. M.; Moore, G. J.; J. Mater. Sci.: Mater. Electron. 2013, 24, 3352.

Figure 1
Chemical structure of poly(3-methylthiophene) (P3MT) and poly(3-octylthiophene) (P3OT) respectively

Because P3ATs have alternating single (σ) and double (π) bonds, the overlapping of p_z orbitals causes a delocalization of π bonds along the chain-forming degenerate bonding and anti-bonding orbitals. Consequently, quasi-continuous energy levels are formed, and the bands formed by degeneracy are called the valence band (VB) and conduction band (CB). The energetic difference between the valence and conduction bands (bandgap) determines if the polymer is conductive, semiconductive, or insulating.¹1 Freitas, J. N.; Pivrikas, A.; Nowacki, B.; Akcelrud, L. C.; Sariciftci, N. S.; Nogueira, A. F.; Synth. Met. 2010, 160, 1654.^,⁷7 Maia, G. A. R.; Larsson, L. F. G.; Viomar, A.; Matos, L. A. C.; Antunes, S. R. M.; Maia, E. C. R.; Oliveira, M. F.; Cunha, M. T.; Rodrigues, P. R. P.; J. Mater Sci.: Mater. Electron. 2016, 27, 8271.

Use of thiophene copolymers (a combination of two or more polymers) has already been demonstrated and was studied by Freitas et al.,⁸8 de Freitas, J. N.; Li, R. W. C.; Nogueira, A. F.; Gruber, J.; Mater. Chem. Phys. 2011, 130, 223. who observed their advantages compared to those of obtained by using the individual polymers separately, but no comparative studies of the use of different oxides have been published as yet.

This work aims to produce and electrochemically characterize hybrid solar cells produced with ZnO and TiO₂ oxides using poly(3-octylthiophene) and poly(3-methylthiophene) (P3OT/P3MT) as a sensitized copolymer.

EXPERIMENTAL SECTION

ZnO particle synthesis

ZnO particles were synthesized by a coprecipitation method (Figure 2).⁹9 Kashyout, A. B.; Soliman, M.; el Gamal, M.; Fathy, M.; Mater. Chem. Phys. 2005, 90, 230.

Figure 2
Flow chart for the ZnO synthesis by coprecipitation method

Solar cell fabrication

Counter electrode

Platinum electrodeposited on FTO was used as the counter electrode. Three electrodes were used in the electrochemical cell: an Ag/AgCl reference electrode, a platinum plate counter electrode, and an FTO working electrode. The electrolytic solution was prepared with K₂PtCl₆ 1x10^-4 mol L^-1 in 0.1 mol L^-1 of HCl. The cyclic voltammetric deposition was performed in four cycles with a potential range of E varying from -0.5 V to 0.5 V at a scanning speed of 20 mV s^-1.

Photoanode

The working electrode was constituted from the synthesized ZnO or TiO₂ (Sigma-Aldrich, 25 nm particle size) deposited over fluorine-doped tin oxide (FTO) substrates. To deposit oxides on FTO, a suspension was produced consisting of: 3 g of ZnO or TiO₂, 0.1 mL of Triton X-100 (VETEC), 0.1 mL of 99.5% acetylacetone (VECTEC) and 4 mL of bidistilled H₂O.¹⁰10 Parussulo, A. L. A.; Tese de Doutorado, Universidade de São Paulo, Brasil, 2013. The deposition of the films was performed by spin coating at 2500 rpm for 20 s with 3 consecutive layers. After the depositions, the films were heated at 450 °C for 30 min.¹¹11 Pereira, É. A.; Montanhera, M. A.; Spada, E. R.; Paula, F. R.; 21º CBECIMAT - Congresso Brasileiro de Engenharia e Ciência dos Materiais, Cuiabá, Brasil, 2014. The ZnO and TiO₂ coated films after calcination were immersed in a P3OT/P3MT solution for 24 h to adsorption.⁷7 Maia, G. A. R.; Larsson, L. F. G.; Viomar, A.; Matos, L. A. C.; Antunes, S. R. M.; Maia, E. C. R.; Oliveira, M. F.; Cunha, M. T.; Rodrigues, P. R. P.; J. Mater Sci.: Mater. Electron. 2016, 27, 8271.

Solar cell

The solar cell was assembled in a “sandwich” form, with the photoanode and counter electrode joined and an electrolytic solution between the plates. The electrolyte used consisted of 0.1 mol L^-1 LiI, 0.05 mol L^-1 I₂, and 0.5 mol L^-1 4-tert-butyl pyridine in acetonitrile. The active cell area was measured to be 0.2 cm², as shown in Figure 3.

Figure 3
Schematic diagram of the solar cell structure

Characterization of ZnO and TiO₂ structures

Powder X-ray diffraction (XRD) patterns were recorded as Bruker DRX D2 Phaser instrument using CuK_α radiation source with a wavelength of 1.5 nm operated at 30 kV and 10 mA, a scan speed of 0.5° s^-1, using a LynxEye detector. The diffraction angle was varied from 20° to 75°.

Scanning electronic microscopy (SEM) images were collected with a TESCAN^® VEGA3 SEM with an SE detector and a tungsten filament at 20 kV and a working distance of 10 mm.

Electrochemical characterization of solar cells

The characterization of the solar cell systems was performed in a Zahner potentiostat, Zennium Electrochemical Workstation model, linked to XPot and a LOT Oriel-Quantum Design GmbH-solar simulator, with a xenon lamp and a beam diameter of 25 mm. The measurements were performed under illumination of 100 mW cm^-2 within a cell area of 0.2 cm², with a standard solar spectrum at AM 1.5G.

Electrochemical impedance spectroscopy (EIS) measurements were performed over a frequency range of 10 kHz-0.01 Hz. The perturbation potential applied was ±10 mV relative to V_oc. Photochronoamperometry measurements were performed for 660 s, with the lamp being interrupted in intervals of 60 s.

Current versus potential curves (j-V) were measured to obtain the photovoltaic parameters of the cells and calculate the energy conversion efficiency of the systems.

RESULT AND DISCUSSION

Figures 4 and 5 shows the X-ray diffractograms of TiO₂ and ZnO particles, respectively.

Figure 4
X-ray diffractogram of anatase TiO₂ particles

Figure 5
X-ray diffractogram of ZnO particles synthesized by co-precipitation

The TiO₂ used presented peaks characteristic of single phase crystalline anatase particles. The main and most intense peak was observed at a 2θ angle of 25.30° can be indexed to the (101) plane, while the other diffraction peaks observed at 37.82°, 48.04°, 53.91°, 55.08°, 62.62°, 68.70°, and 7.41°, are the (112), (200), (105), (211), (204), (116), and (220) planes of the TiO₂ anatase unit cell.¹¹11 Pereira, É. A.; Montanhera, M. A.; Spada, E. R.; Paula, F. R.; 21º CBECIMAT - Congresso Brasileiro de Engenharia e Ciência dos Materiais, Cuiabá, Brasil, 2014. The observed peaks were narrow and well-defined, indicating the organized structure of a crystalline and homogeneous powder. No secondary peaks were observed, which affirmed the high purity of TiO₂¹²12 Oliveira, P. L.; Araújo, D. S.; Costa, A. C. F. M.; Oliveira, L. S. C.; 22º CBECiMat - Congresso Brasileiro de Engenharia e Ciência dos Materiais, Natal, Brasil, 2016. The cataloging of the peaks was performed by comparison with the crystallographic record PDF 71-1166 using EVA^® software referring to TiO₂ anatase phase.

XRD was used to identify crystalline phases and the XRD results confirmed that the ZnO particles consisted of a wurtzite crystalline phase,¹³13 Gusatti, M.; Rosário, J. A.; Barroso, G. S.; Campos, C. E. M.; Riella, H. G.; Kunhen, N. C.; Chem. Eng. Trans. 2009, 17, 1017. with intense diffraction peaks at 2θ values of 31.78°, 34.78°, and 36.30°, which correspond, respectively, to the (100), (002), and (101) planes, and peaks at 2θ values of 47.83°, 56.52°, 63.12°, 66.78°, 67.89°, and 69.37°, which can be indexed to the (102), (110), (103), (200), (112), and (201) planes, respectively, indicating the unitary cells in a hexagonal compact system that are characteristic of ZnO.¹⁴14 Maia, G. A. R.; Larsson, L. F. G.; Viomar, A.; Maia, E. C. R.; de Santana, H.; Rodrigues, P. R. P.; Ceramica (Sao Paulo, Braz.). 2016, 62, 361.

The diffractogram (Figure 5) shows only primary peaks; there were no peaks that did not belong to ZnO, indicating that the crystals were of high crystallinity and free from impurities. The obtained peaks are narrow, well-defined, and intense, indicating a high degree of structural organization and consequently, a crystalline and homogeneous powder.¹⁵15 Hermínio, D. F.; Dissertação de Mestrado, Universidade Federal de Pernambuco, Brasil, 2012. The cataloging of the peaks was performed by comparison with the crystallographic record PDF 01-075-0576 using EVA software, referring to pure ZnO.

Figure 6 shows SEM images of the oxide samples being analyzed.

Figure 6
SEM images of (a) ZnO and (b) TiO₂

In Figure 6, the SEM images demonstrate the spherical morphology of the synthesized ZnO and the particles presented mean sizes of 600 ± 100 nm. The morphology of the ZnO particles is very sensitive to factors such as the reaction time, concentration and synthesis temperature.¹⁶16 Li, D.; Haneda, H.; Chemosphere 2003, 51, 129. This spherical morphology is characteristic of the coprecipitation method and precursor concentration used. Fan et al.,¹⁷17 Fan M.; Jing Y.; Yue-Qin D.; Zhi-Hao Y.; Li-Jian B.; Sens. Actuators, B 2011, 156, 703. reported nanosphere formation from this production method using others precursors, specifically hexamethylenetetramine, (CH₂)₆N₄, zinc nitrate (Zn(NO₃)₂), and Na₃C₆H₅O_7, as a surfactant.¹⁸18 Mayrinck, C.; Rocha, L. A.; Vitoreti, A. B. F.; Vaz, R.; Tartuci, L. G.; Ferrari, J. L.; Schiavon, L. A.; Rev. Virtual Quim. 2017, 9, 717.

The TiO₂ particles did not exhibit a well-defined morphology, instead of taking the form of clusters. According to Costa et al.,¹⁹19 Costa, A. C. F. M.; Ramalho, M. A. F.; Neiva, L. S.; Alves-Jr. S.; Kiminami, R. H. G. A.; Gama, L.; Revista Eletrônica de Materiais e Processos 2007, 2.3, 14. Pratsinis,²⁰20 Pratsinis, S. E.; Prog. Energy Combust. Sci. 1997, 24, 197. and Hong et al.,²¹21 Hong, R.Y.; Li, J. H.; Chen, L. L.; Liu, D. Q.; Li, H. Z.; Zheng, Y.; Ding, J.; Powder Technol. 2009, 189, 426. particles smaller than 1 µm tend to agglomerate because of the high surface energy associated with the extensive surface area of such small particles. Muniz et al.²²22 Muniz, E. C.; Goes, M. S.; Silva, J. J.; Varela, J. A.; Joanni, E.; Parra, R.; Bueno, P. R.; Ceram. Int. 2011, 37, 1017. proved that TiO₂ anatase presented a higher clustering density and higher surface area per unit volume in relation to the rutile phase and the brookite phase, increasing its use as an electron acceptor.²³23 Guimaraes, R. R.; Paurussulo, A. L. A.; Matias, T. A.; Toma, H. E.; Araki, K.; Electrochim. Acta. 2017, 255, 92.^,⁴4 Vitoreti, A. B. F.; Vaz, R.; Pena, A. L.; Raphael, E.; Ferrari, J. L.; Schiavon, M. A.; Rev. Virtual Quim. 2017, 9, 4.

In order to evaluate the cell response to the incident light, EIS measurements were performed for the devices in the presence of light, and the results are presented in the Nyquist diagram (Figure 7).

Figure 7
Nyquist type EIS diagram obtained for solar cells of ZnO and TiO₂ with P3OT/P3MT copolymer under illumination of 100 mW cm^-2

The Nyquist diagram shows that for the ZnO+P3OT/P3MT solar cell there is only one capacitive arc with higher impedance values than those observed for the TiO₂+P3OT/P3MT cell. The impedance response indicates that the ZnO cell presents greater resistance to the photocurrent generation processes.

Three capacitive arcs were seen for the TiO₂+P3OT/P3MT cell. The first arc, at high frequency, corresponds to the charge transfer process in the platinum counter electrode. In the intermediate frequency region, there is a second capacitive arc related to the charge recombination process and electrons transport in the conduction band of the working electrode.

The third arc can be observed at low frequencies and is related to the Nernstian diffusion process in the electrolyte, I^-/I₃ ^-. This process of electron transfer with I₃ ^- ions occurs at the semiconductor/electrolyte interface.²²22 Muniz, E. C.; Goes, M. S.; Silva, J. J.; Varela, J. A.; Joanni, E.; Parra, R.; Bueno, P. R.; Ceram. Int. 2011, 37, 1017.

It is observed variations in the diameter of the semicircles corresponding to changes in the charge transfer resistance of the film with different oxides. The TiO₂+P3OT/P3MT cell presented the smallest semicircle, indicating the lowest resistance to charge transfer, showing TiO₂+P3OT/P3MT to be more photosensitive than ZnO+P3OT/P3MT.

The TiO₂+P3OT/P3MT cell presented a capacitive arc corresponding to the platinum counter electrode, indicating better injection of electrons on the surface of the semiconductor and consequently a greater efficiency in photon collection. ZnO cells are known to only present a capacitive arc when inefficient cells are produced, usually using dyes derived from biomass, which are poor devices for energy conversion.²⁴24 Ricchariya, G.; Kumar, A.; Opt. Mater. 2018, 79, 296.

25 Ghan, W.; Kang, H.; Sheikh, T.; Yadav, S.; Gil, T. C.; Nesbitt, F.; Uddin, J.; Sci. Rep. 2017, 7, 41470.^-²⁶26 Latif, M. S. A; Abuiridan, M. B.; Dahoudi, N. A.; Kahlout, A, M.; Taya, S. A.; Agez, T. M.; Ghamri, H. S.; Science, Technology and Development 2015, 34, 135.

The Bode phase angle diagrams (Figure 8) present three-time constants for the TiO₂+P3OT/P3MT solar cell. The first constant, observed at a frequency of 1000 Hz, is associated with the charge transfer process on the platinum counter electrode with a phase angle of 20°. The second time constant, observed in the 1-Hz frequency region, corresponds to charge recombination and processes that involve the transport of electrons in the conduction band of the working electrode with a phase angle of 26°. The third constant might be observed at frequencies between 0.1 and 0.01 Hz and is assigned to the Nernstian diffusion process in the I^-/I₃^- electrolyte, with a phase angle of 7°.

Figure 8
EIS diagram of the Bode phase angle obtained under 100 mW cm-² illumination of ZnO and TiO₂ solar cells with P3OT/P3MT copolymer

For the ZnO+P3OT/P3MT cell, three-time constants were observed, but the processes could not be clearly separated. A region of constant phase angle that can be observed between frequencies of 1000 and 100 Hz is associated with an overlap of the charge transfer processes in the platinum counter electrode and charge recombination and electron transport in the conduction band of the working electrode.

Charge transfer in the counter electrode was noted at 300 Hz for the ZnO+P3OT/P3MT cell with a phase angle of 49.2°. For this cell, charge recombination and electron transport in the conduction band of the working electrode were observed at 85 Hz with a phase angle of 48.6°. The time constant for the Nernstian diffusion in the I/I₃^- electrolyte was between 0.1 Hz and 0.01 Hz with a phase angle of 3°.

In the TiO₂ cell, the displacement to higher frequencies with lower phase angles of the time constant for charge transfer in the counter electrode indicates a faster response in the photocurrent generation with a higher efficiency. This response, at lower frequencies and lower phase angles for recombination and electron transport, indicates that in the TiO₂ cell, the electron lifetime is longer and the recombination processes are less favored compared to the ZnO solar cell. The lower phase angle values determined for the diffusion process in the ZnO cell indicates the recombination of injected electrons, regenerating the copolymer and minimizing electrolyte diffusion.

In Figure 9, the photochronoamperometry measurements for the systems are analyzed.

Figure 9
Photochronoamperometry measurements for samples under 100 mW cm^-2 of illumination. The lamp was interrupted at a time interval of 60 s

It can be seen in Figure 9 that the TiO₂+P3OT/P3MT the cell presented a photocurrent of approximately J_sc = 1.4 mA cm^-2, while the ZnO+P3OT/P3MT cell showed J_sc = 0.8 mA cm^-2 The use of the copolymer caused the photocurrent increase by 14 times to the TiO₂+P3OT/P3MT cell in relation to TiO₂. To the cell ZnO+P3OT/P3MT the increase was the 2 times bigger than the ZnO, proving the high electron injection capacity of the surface of the semiconductor. These results also indicate that the interactions between TiO₂ and copolymers are more pronounceable when compared to ZnO film.

As related by Gratzel,²⁷27 Grätzel, M.; Nature 2001, 414, 338. the size of the particle is a limiting factor in the production of charge injection in thirth generation of photovoltaic systems. When reaching nanometric dimensions, the materials acquire new mechanical, electrical, chemical and optical properties, because a confinement of electrons occurs in their interior, making their properties more accentuated. Among them, the increase of the surface area of the particles and a greater porosity, allows larger amounts of polymer adsorbed, generating high efficiency solar cells.

It was also verified that all systems presented a high on/off ratio and fast switching because when light impinged on the cell, the current increase was instantaneous, and when the lamp was interrupted, the current for both systems was close to zero. This proves that the reactions that govern the device are extremely fast. Regarding the stability of the devices, it was verified that both remained stable during the analysis period.

Only small current decays were observed, which are related to the diffusion processes at the interface of the device. According to Valério et al.²⁸28 Valério, T. L.; Maia, G. A. R.; Viomar, A.; Dias, B. V.; Rodrigues, P. R. P.; Orbital: Electron. J. Chem. 2018, 10, 234. and Essner,²⁹29 Essner, J.; Dissertação de Mestrado, Kansas State University, Estados Unidos, 2011. the rate of reduction of the triiodide ions at the cathode does not follow the oxidation rate of the iodide ions at the anode, so some polymer molecules remain in the oxidized state until a triiodide molecule can reach the oxide to reduce it. At the moment the reduced species of the electrolyte arrives at the surface of the anode is immediately oxidized without being able to penetrate the porous oxide, so the polymer molecules that are in the deeper layers of the oxide remain oxidized and the drop in current can be observed, however, after a few seconds, J_sc stabilized.

Figure 10 shows j-V plots of the cells which were analyzed.

Figure 10
Typical j-V curves obtained from the cells analyzed under 100 mW cm^-2 of simulated solar irradiation

Using the results shown in Figure 10, it was possible to determine the photovoltaic parameters of the devices listed in Table 1 and calculate the energy conversion efficiency (η) using Equation 1, being that, V_oc = open-circuit potential, J_sc = short-circuit current, FF = fill factor and P_in = solar irradiation, of 100 mWcm^-2.³⁰30 Narayan, M. R.; Renewable Sustainable Energy Rev. 2012, 16, 208.

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Table 1
Parameters obtained from the j-V curves of TiO2 and ZnO cell sensitized with copolymer P3OT/P3MT

The current is associated with the electron injection mechanism and the charge carrier transport. It reaches its maximum when the electric voltage is zero and when a potential is applied, the current decays, as there is an increase in the resistance.¹⁴14 Maia, G. A. R.; Larsson, L. F. G.; Viomar, A.; Maia, E. C. R.; de Santana, H.; Rodrigues, P. R. P.; Ceramica (Sao Paulo, Braz.). 2016, 62, 361. It was observed that the cells presented a high V_oc of 0.615 ± 0.004 V and 0.623 ± 0.024 V for TiO₂ and ZnO, respectively, similar to the values found for cells using high-performance photoelectrochemical dyes. Guimaraes et al.²²22 Muniz, E. C.; Goes, M. S.; Silva, J. J.; Varela, J. A.; Joanni, E.; Parra, R.; Bueno, P. R.; Ceram. Int. 2011, 37, 1017. reached values of V_oc = 0.600 V and V_oc = 0.610 V for TiO₂ devices using ruthenium-based dyes.

The excellent fill factor results for the TiO₂ cell should also be noted. The FTO/TiO₂/P3OT-P3MT system presented values of FF = 0.617 ± 0.117, approaching the best values found when using ruthenium-based dyes as photosensitizers (FF ~ 0.7).³¹31 Zhao, J.; Wu, J.; Zheng, M.; Huo, J.; Tu, Y.; Electrochim. Acta. 2015, 156, 261.

The cell with the highest energy conversion efficiency was produced with the anode interface FTO/TiO₂/P3OT-P3MT, yielding approximately 0.617% ± 0.117. It is observed that the efficiency values obtained are closely related to the photocurrent density generated by the system since the ZnO cell presented a photocurrent (J_sc = 0.719 ± 0.109 mA cm^-2) about 47% lower than that of the TiO₂ cell (J_sc = 1.545 ± 0.240 mA cm^-2). The efficiency may also be associated with the morphology of the oxide used. Since TiO₂ presented a smaller particle size, it has a higher surface area available for the adsorption of the polymer. With increased adsorption, the flow of electrons during the operation of the solar cell is consequently increased. The copolymer was able to form electron-hole pairs, as improved photocurrent values were obtained, proving that it is efficient in charge injection.³²32 Wongcharee, K.; Meeyoo, V.; Chavadej, S.; Sol. Energy Mater. Sol. Cells. 2007, 91, 556.

33 Kumara, N. T. R. N.; Ekanayake, P.; Lim, A.; Iskandar, M.; Ming, L. C.; J. Sol. Energy Eng. 2013, 135, 031014.^-³⁴34 Sonai, G. G.; Melo, M. A.; Nunes, J. H. B.; Megiatto Jr., J. D.; Nogueira, A. F.; Quim. Nova 2015, 38, 1357.

CONCLUSION

The X-ray diffractograms showed high purity and crystallinity of both oxides, TiO₂ and ZnO, which exhibited anatase and wurtzite hexagonal phases, respectively. The SEM images demonstrated the spherical morphology of ZnO, while TiO₂ formed agglomerates because of its high surface area and small particle size.

Electrochemical characterization of the cells indicated TiO₂ as the best oxide for use in solar cells sensitized by copolymers, since this cell presented lower charge transfer resistance, as determined by electrochemical impedance spectroscopy (EIS), and a higher current density value j_TiO2 = 1.545 mA cm^-2, achieving an efficiency of 0.617%. The copolymer proved to be a satisfactory charge donor, as photochronoamperometry experiments showed an increase of 14 times in the current for the TiO₂ cell and 2 times for ZnO when compared to non-sensitized oxides.

ACKNOWLEDGMENT

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001. Acknowledgment to CNPq, SETI/UGF, FINEP.

REFERENCES

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²
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¹¹
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¹²
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¹⁴
Maia, G. A. R.; Larsson, L. F. G.; Viomar, A.; Maia, E. C. R.; de Santana, H.; Rodrigues, P. R. P.; Ceramica (Sao Paulo, Braz.). 2016, 62, 361.
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Costa, A. C. F. M.; Ramalho, M. A. F.; Neiva, L. S.; Alves-Jr. S.; Kiminami, R. H. G. A.; Gama, L.; Revista Eletrônica de Materiais e Processos 2007, 2.3, 14.
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Pratsinis, S. E.; Prog. Energy Combust. Sci. 1997, 24, 197.
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Hong, R.Y.; Li, J. H.; Chen, L. L.; Liu, D. Q.; Li, H. Z.; Zheng, Y.; Ding, J.; Powder Technol 2009, 189, 426.
²²
Muniz, E. C.; Goes, M. S.; Silva, J. J.; Varela, J. A.; Joanni, E.; Parra, R.; Bueno, P. R.; Ceram. Int. 2011, 37, 1017.
²³
Guimaraes, R. R.; Paurussulo, A. L. A.; Matias, T. A.; Toma, H. E.; Araki, K.; Electrochim. Acta 2017, 255, 92.
²⁴
Ricchariya, G.; Kumar, A.; Opt. Mater. 2018, 79, 296.
²⁵
Ghan, W.; Kang, H.; Sheikh, T.; Yadav, S.; Gil, T. C.; Nesbitt, F.; Uddin, J.; Sci. Rep. 2017, 7, 41470.
²⁶
Latif, M. S. A; Abuiridan, M. B.; Dahoudi, N. A.; Kahlout, A, M.; Taya, S. A.; Agez, T. M.; Ghamri, H. S.; Science, Technology and Development 2015, 34, 135.
²⁷
Grätzel, M.; Nature 2001, 414, 338.
²⁸
Valério, T. L.; Maia, G. A. R.; Viomar, A.; Dias, B. V.; Rodrigues, P. R. P.; Orbital: Electron. J. Chem 2018, 10, 234.
²⁹
Essner, J.; Dissertação de Mestrado, Kansas State University, Estados Unidos, 2011.
³⁰
Narayan, M. R.; Renewable Sustainable Energy Rev. 2012, 16, 208.
³¹
Zhao, J.; Wu, J.; Zheng, M.; Huo, J.; Tu, Y.; Electrochim. Acta 2015, 156, 261.
³²
Wongcharee, K.; Meeyoo, V.; Chavadej, S.; Sol. Energy Mater. Sol. Cells 2007, 91, 556.
³³
Kumara, N. T. R. N.; Ekanayake, P.; Lim, A.; Iskandar, M.; Ming, L. C.; J. Sol. Energy Eng. 2013, 135, 031014.
³⁴
Sonai, G. G.; Melo, M. A.; Nunes, J. H. B.; Megiatto Jr., J. D.; Nogueira, A. F.; Quim. Nova 2015, 38, 1357.

Publication Dates

Publication in this collection
02 May 2019
Date of issue
Mar 2019

History

Received
21 Sept 2018
Accepted
11 Dec 2018
Published
23 Jan 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Gusatti, M.; Rosário, J. A.; Barroso, G. S.; Campos, C. E. M.; Riella, H. G.; Kunhen, N. C.; Chem. Eng. Trans 2009, 17, 1017.

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Maia, G. A. R.; Larsson, L. F. G.; Viomar, A.; Maia, E. C. R.; de Santana, H.; Rodrigues, P. R. P.; Ceramica (Sao Paulo, Braz.). 2016, 62, 361.

[15] ¹⁵
Hermínio, D. F.; Dissertação de Mestrado, Universidade Federal de Pernambuco, Brasil, 2012.

[16] ¹⁶
Li, D.; Haneda, H.; Chemosphere 2003, 51, 129.

[17] ¹⁷
Fan M.; Jing Y.; Yue-Qin D.; Zhi-Hao Y.; Li-Jian B.; Sens. Actuators, B 2011, 156, 703.

[18] ¹⁸
Mayrinck, C.; Rocha, L. A.; Vitoreti, A. B. F.; Vaz, R.; Tartuci, L. G.; Ferrari, J. L.; Schiavon, L. A.; Rev. Virtual Quim. 2017, 9, 717.

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Costa, A. C. F. M.; Ramalho, M. A. F.; Neiva, L. S.; Alves-Jr. S.; Kiminami, R. H. G. A.; Gama, L.; Revista Eletrônica de Materiais e Processos 2007, 2.3, 14.

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Pratsinis, S. E.; Prog. Energy Combust. Sci. 1997, 24, 197.

[21] ²¹
Hong, R.Y.; Li, J. H.; Chen, L. L.; Liu, D. Q.; Li, H. Z.; Zheng, Y.; Ding, J.; Powder Technol 2009, 189, 426.

[22] ²²
Muniz, E. C.; Goes, M. S.; Silva, J. J.; Varela, J. A.; Joanni, E.; Parra, R.; Bueno, P. R.; Ceram. Int. 2011, 37, 1017.

[23] ²³
Guimaraes, R. R.; Paurussulo, A. L. A.; Matias, T. A.; Toma, H. E.; Araki, K.; Electrochim. Acta 2017, 255, 92.

[24] ²⁴
Ricchariya, G.; Kumar, A.; Opt. Mater. 2018, 79, 296.

[25] ²⁵
Ghan, W.; Kang, H.; Sheikh, T.; Yadav, S.; Gil, T. C.; Nesbitt, F.; Uddin, J.; Sci. Rep. 2017, 7, 41470.

[26] ²⁶
Latif, M. S. A; Abuiridan, M. B.; Dahoudi, N. A.; Kahlout, A, M.; Taya, S. A.; Agez, T. M.; Ghamri, H. S.; Science, Technology and Development 2015, 34, 135.

[27] ²⁷
Grätzel, M.; Nature 2001, 414, 338.

[28] ²⁸
Valério, T. L.; Maia, G. A. R.; Viomar, A.; Dias, B. V.; Rodrigues, P. R. P.; Orbital: Electron. J. Chem 2018, 10, 234.

[29] ²⁹
Essner, J.; Dissertação de Mestrado, Kansas State University, Estados Unidos, 2011.

[30] ³⁰
Narayan, M. R.; Renewable Sustainable Energy Rev. 2012, 16, 208.

[31] ³¹
Zhao, J.; Wu, J.; Zheng, M.; Huo, J.; Tu, Y.; Electrochim. Acta 2015, 156, 261.

[32] ³²
Wongcharee, K.; Meeyoo, V.; Chavadej, S.; Sol. Energy Mater. Sol. Cells 2007, 91, 556.

[33] ³³
Kumara, N. T. R. N.; Ekanayake, P.; Lim, A.; Iskandar, M.; Ming, L. C.; J. Sol. Energy Eng. 2013, 135, 031014.

[34] ³⁴
Sonai, G. G.; Melo, M. A.; Nunes, J. H. B.; Megiatto Jr., J. D.; Nogueira, A. F.; Quim. Nova 2015, 38, 1357.

Semiconductor	J_sc (mA cm^-2)	V_oc (V)	FF	η (%)
TiO₂	1.545 ± 0.240	0.615 ± 0.004	0.637 ± 0,003	0.617 ± 0.117
ZnO	0.719 ± 0.109	0.623 ± 0.024	0.496 ± 0,033	0.215 ± 0.035

Brasil