Open-access Natural dyes from amazon forest: potential application in dye-sensitized solar cells

Corantes naturais da floresta Amazônica: potenciais aplicações em células solares fotosensibilizadas por corante

ABSTRACT

In this work, plant dyes extracted from Amazon Forest are applied as a sensitizer in Dye-Sensitized Solar Cells. The selected plants were Euterpe oleracea, Arrabidaea chica, Bixa orellana, Genipa Americana, and Myrcia sylvatica, and the dyes were collected from fruits, leaves, seeds, pulp and seeds and stalk scrapings respectively. Characterization studies by the UV-vis spectroscopy made it possible to know the absorption spectra of each plant dye, and the X-ray diffraction technique allows the structural characterization of the nanostructured semiconductor layer. The solar cells were characterized according to their efficiency parameters (Voc, Jsc, FF and ? (%)), obtained from the current vs voltage curves. Such parameters proved to be modest, presenting Voc and Jsc values over 0.334 volts and 0.452 mA/cm2 for a photosensitized cell with the dyes extracted from Genipa americana. In this way, it was possible to verify the photoelectrochemical potential of the dyes extracted from plants of the Amazon Forest.

Keywords Plants dyes; DSSC; Grätzel Cell; solar cell; Amazon Forest

RESUMO

Neste trabalho são aplicados corantes extraídos de plantas da Floresta Amazônica como sensibilizadores em células solares sensibilizadas por corantes. As plantas selecionadas foram Euterpe oleracea, Arrabidaea chica, Bixa orellana, Genipa americana e Myrcia sylvatica e os corantes foram coletados de frutos, folhas, sementes, polpa e sementes e do caule, respectivamente. Os estudos de caracterização através da espectroscopia UV-vis possibilitaram conhecer os espectros de absorção para cada corante e a técnica de difração de raios X permitiu a caracterização estrutural da camada semicondutora nanoestruturada. As células solares foram caracterizadas quanto a seus parâmetros de eficiência (Voc, Jsc, FF e ? (%)), obtidas das curvas de corrente vs potencial. Tais parâmetros se mostraram modestos, apresentando valores de Voc sobre os 0,334 volts e Jsc de 0,452 mA/cm2 para célula fotossensibilizada com o corante extraído da Genipa americana. Dessa forma foi possível verificar o potencial fotoeletroquímico dos corantes extraídos de plantas da Floresta Amazônica.

Palavras-chave corante vegetal; DSSC; célula de Grätzel; célula solar; Floresta Amazônica

1. INTRODUCTION

The yearning for new and less polluting, environment-friendly energy sources has driven research growth in pursuit of alternative energy in recent decades. Despite the growing advance related to clean technologies, global energy demand is currently still supplied, in a greater percentage, by fossil fuels (non-renewable), reaching 81.1% in the global energy matrix [1, 2].

Due to its high potential, solar energy presents itself as one of the most promising alternatives. The earth receives about ten thousand times more energy from the sun than our daily global consumption [3]. Even though the estimate is encouraging, the photovoltaic market is represented mainly by mono and polycrystalline silicon solar cell technologies that have an estimated production cost of US$0,23/W. Many developing countries do not have this renewable source of energy due to its commercialization. Thus, the discoveries of new materials and technologies with low environmental impact, national sources is a way to lower cost prices [4-6].

The Dye-Sensitized Solar Cells (DSSCs) were reported for the first time in 1991 when Michael Grätzel reported a new low-cost photovoltaic device configuration. In 2019 the National Renewable Energy Laboratory (NREL) reported an efficiency certification of 12.3% for the DSSC fabricated by the École Polytechnique Fédérale de Lausanne (EPFL) [7, 8]. The typical configuration of the Grätzel devices involved the photoanode formed by the deposition of a nanostructured inorganic semiconductor (TiO2) layer on transparent conductive glass (Indium Tin Oxide (ITO)/glass) sensitized with N719 in contact with a counter electrode formed by ITO/glass through the non-aqueous liquid electrolyte. Due to the high cost and environmental impacts of the ruthenium complex, other dyes have been considered as sensitized compounds easily obtainable, with low-costs and low environmental impact like plant dyes [9, 10].

The Amazon forest is the world's largest intact forest; it is considered the birthplace of a wide variety of natural dyes that can successfully be applied to DSSC’s. Natural dyes can be easily obtained by a simple extraction method from leaves, flowers, bark, seeds, and other parts. They are distinguished by how it is incorporated into the material surface, their solubility, particle or molecular size, and chemical composition [11]. In DSSC’s, dyes will guarantee the photo injection of charges in the conduction band of the semiconductor [7]. The interaction process occurs through alcoholic condensation and the chelating effect, guaranteed by hydroxyl groups (-OH) and carboxyl groups (-COOH) present in non-anthocyanin flavonoids, anthocyanins, carotenoids, and chlorophylls [2, 12].

In this work, we applied plant dyes from Amazon Forest as a sensitizer in DSSC’s. The selected plants were Euterpe oleracea, Arrabidaea chica, Bixa orellana, Genipa Americana, and Myrcia sylvatica and the dyes were collected from fruits, leaves, seeds, pulp and seeds, and stalk scrapings respectively. The UV-vis spectroscopy made it possible to know the respective absorption spectra of each dye and the X-ray diffraction (XRD) technique characterized the semiconductor layer. The electrical characterization allowed obtaining the efficiency parameters of the respective solar cells for each dye.

2. MATERIALS AND METHODS

2.1 Materials

The following reagents were used in this work: acetone, isopropanol, methanol, and ethylene glycol, acquired from Synth®, and acetonitrile and potassium iodide acquired from Biotec®. Granulated metallic iodine, 20 µm graphite, and TiO2 paste from Sigma Aldrich® were also used. The conductive substrate used was ITO (Glass Coated Indian Tin Oxide) with a surface resistivity of 15 Ω/sq, obtained from Lumtech. The solutions were prepared using the Millipore water, Milli-Q® purification system.

2.2 Dyes extraction procedure

Table 1 summarizes the respective parts of each plant used to obtain the dyes. For extracting the dye, 1 mL of methanol was used for each gram (g) of the raw plant material, mixed by magnetic stirring for 15 minutes, followed by resting for 2 hours before being filtered [13, 14]. The obtaining dyes were placed in the amber flask to protect them from light.

Table 1
Plants and the used parts.

Figure 1 shows pictures of each plant part used in this work and the respective dye.

Figure 1
Dyes and plant parts used in the study. A) Myrcia sylvatica, B) Bixa orellana, C) Euterpe oleracea, D) Genipa Americana, E) Arrabidaea chica

2.3 Characterization

Optical characteristics of each dye were obtained through the absorption spectra collected with a Thermo Scientific UV-vis spectrophotometer model GENESYS™ 10S between the 400 to 700 nm electromagnetic spectrum region. The crystallographic characterization of the semiconductor layer of TiO2 was performed using a Rigaku D-max Diffractometer. The measurements were performed at room temperature using CuKα radiation in the range of 15𝟢 ≤ 2θ ≤ 80𝟢 with 0.02𝟢 (2θ) step and counting time of 5s.

2.4 Photoanode and counter electrode preparation

In DSSC’s the photoanode has the important function of absorbing and converting the light into the electric energy. As the ITO/glass is the support for the deposition of the semiconductor layer and the electrical conductivity it is necessary to ensure the perfect cleaning of the conductive ITO surface. The cleaning process was conducted by following the methodology reported by SILVA et. al [16]. Firstly, moistened cotton® swabs in acetone were used to remove the dirt and the grease present on the ITO surface. Next, the substrates were placed in a 9:1 water and industrial detergent, and subjected to mild heating for 10 minutes, after that, the substrates were subjected to successive distilled water washes to remove the detergent. Subsequently, the substrates were placed in an ultrasonic bath for 10 minutes in acetone and then 10 minutes in isopropanol, which remained in the latter until used.

The TiO2 semiconductor layer was deposited on the ITO substrate with an exposed area of 0.25 cm² using the "doctor blade" method. The exposed area was defined by Scotch® tape Magic™ 810, a 0.060 mm thickness previously placed on the substrate. The tape was then removed, and TiO2/ITO/glass was submitted to 300 ºC for 20 minutes to obtain the nanostructured porous TiO2. Subsequently, the substrates were immersed in the sensitizing dye for 12 hours, Figure 2.

Figure 2
Photoanodes immersed in the respective sensitizing dye solutions: (A) Euterpe oleracea, (B) Arrabidaea chica, (C) Bixa orellana, (D) Genipa Americana, (E) Myrcia sylvatica.

The counter electrode is an important component of DSSC’s, it collects charges from external circuits, and it enables the redox process in the electrolyte. In this study, the counter electrode is formed by the ITO/glass substrate with the same dimensions of photoanode and the active area of 0,33 cm² that was covered with graphite [16]. Thereby, the counter electrode modification, either by graphite, platinum (Pt), graphene, conductive polymers, among others, aims to increase the charges mobility and the reduction of electrolyte in the counter electrode interface [16, 17].

2.5 Cell assembly

Figure 3 shows the DSSC’s diagram of the assembly device in this work. The assembly process consists of approximating the photoanode and the counter electrode, without a short-circuit. To obtain this, it was previously placed a parafilm tape with an opening of 0.5 x 0.5 cm on photoanode, exposed the sensitized TiO2. Before the final approach, the non-aqueous liquid electrolyte was placed dripping on the exposed photoanode. Non-aqueous electrolyte, formed by a redox pair (I-3/I), was prepared by dissolving 830 mg of potassium iodide (KI) and 60 mg iodine (I2) in ethylene glycol and acetonitrile (6:4) mixture [18].

Figure 3
Schematic representation of the assembled DSSC device.

2.6 Electrical characterization of the DSSC’s

Solar cells are characterized by the current versus voltage curves (I versus V) that allow them to obtain the necessary efficiency parameters for their evaluation. From the curves are extracted the open circuit potential (Voc) (measured in zero current) and the short-circuit current density (Jsc = Icc/A) (measured in zero potential), where Icc is the short-circuit current, measured externally, and A is the effective area of the cell. The fill factor (FF) of the curve and the energy conversion efficiency (η) are calculated mathematically from the experimental data (I-V curve), equations 1 and 2, respectively.

The fill factor relates to the maximum power with the theoretical power of the cell. This parameter can be obtained from the ratio between these powers (equation 1) and is directly related to the efficiency of the cell. The value of FF varies from 0 to 1, and the closer to 1 the less resistive the system is [19].

FF = J m V m J SC V OC (1)

Energy conversion efficiency (η) was obtained through the ratio between the maximum power (Pmax) and the incident light density (Pin), standardized light incidence at 100 mW/cm² (AM 1.5G) calibrated with digital luximeter (AK310), equation 2.

η = P max P in = J m V m P in (2)

In this work, it was used to characterize the electrical performance of the manufacture DSSCs, a solar simulators system, LSC 100 ORIEL, and galvanostat/potentiostat Autolab PGSTAT 204N.

3. RESULTS AND DISCUSSION

3.1 Plant dyes characterization

The UV-vis spectroscopy technique has allowed the precise verification of the regions of white light absorption by the pigments used, Figure 4. The pigments are responsible for ensuring the current density in the cell, and therefore the importance of the investigation since the absorption region influences considerably the final performance of the device [20]. It is noted in theme-related works that pigments with light absorption in the intermediate region of the visible spectrum are those with the highest energy conversion efficiency [20-24]. Naturally the absorptions in this region (from 500 to 600 nm) are characteristic of anthocyanins, a group of natural phenolic compounds [25].

Figure 4
Standardized UV-vis absorption spectra of natural methanol pigments.

Absorptions (Figure 4), except for the Myrcia sylvática pigment, are evident, showing well-defined peaks in the visible spectrum region. For this pigment no explicit peak of maximum absorption is observed, however, two discrete peaks are noted at 457 nm and 591 nm. Zhou and employees [25] attribute this discrepancy to overlapping absorption peaks. For the other pigments, the most intense peaks can be observed at 540 nm for Euterpe oleracea, 456 nm for Bixa Orellana, 598 nm for Genipa Americana and 500 nm for Arrabidaea chica. Table 3 shows the main classes of molecules present in natural dyes responsible for the light absorption in the visible region.

Table 2
Main class of molecules present in the plant dyes

3.2 Characterization of the nanostructure semiconductor layer

Figure 5 a) shows the X-ray diffraction (XRD) patterns of nanostructured TiO2 deposited as a semiconductor layer on the ITO/glass substrate. Also identified are the rutile (b) and anatase (c) polymorphs characteristic of TiO2 [30-32].

Figure 5
XRD patterns of the nanostructured TiO2 (a) and reported rutile (b) and anatase(c) [29-31].

In DSSCs it is desired that the photoanode is formed by a nanostructured TiO2 mesoporous layer that guarantees a good diffusion of the dye and the electrolyte [33, 34]. XRD technique is used to demonstrate the structural characteristics of the deposited TiO2 layer on the ITO/ glass substrate. Figure 5 a) shows the XRD pattern of TiO2, that presents five characteristic diffractions belonging to the anatase phase attributed to the crystalline planes at 25.86 (101), 38.36 (112), 48.58 (020), 69.34 (220), and 75.62 (215) with tetragonal structure, spatial group I41/amdZ and symmetry 141 [30], five other peaks were attributed to the ITO/glass substrate at 30.68 (222), 35.72 (411), 50.86 (440), 54.5 (121), and 60.48 (622), and three peaks, 28.04 (110), 55.74 (220), and 63.16 (002) to the rutile phase with tetragonal structure, space group P42/mnm, and symmetry 136 [32]. According to the XRD analysis, the TiO2 layer shows the rutile and anatase characteristics in accordance with the recommended composition reported for applications in DSSCs [35 - 39].

3.3 Electrical characterization of DSSCs

The photoelectrochemical parameters of the cells sensitized with these pigments are organized in Table 3. The cells were evaluated according to open circuit voltage (Voc), short-circuit current density (Jsc), fill factor (FF), and energy conversion efficiency (η).

Table 3
Electrical parameters of DSSCs sensitized with plant dyes.

The energy conversion efficiencies (η) obtained for these cells are modest, ranging from 0.01 to 0.08%. The voltage (Voc) and current density (Jsc) values displayed ranged from 0.283 to 0.334 volts and 0.141 and 0.452 mA/cm2, respectively. The most expressive performance is shown for the cell whose sensitization was performed with the pigment extracted from Genipa americana, Table 3. However, plant dyes have not shown the best energy conversion efficiencies in DSSCs [10]. Some factors like the instability by the temperature variations [2] and the device assembly [40] may contribute to the low performance of DSSCs.

Figure 6 shows two of the experimental curves obtained from the devices using the pigments of Arrabidaea chica and Euterpe oleracea. The dotted rectangles were placed to show the differences between the ideal and experimental maximum power presented by the devices. In general, the experimental cells presented low values of FF, ranging from 0.2 to 0.5, considered quite resistive systems. The effects can be noted in the efficiency values, in which the resistivity interferes directly [19].

Figure 6
IV curves of DSSCs sensitized by extracted dyes of Arrabidaea chica and Euterpe oleracea. Black and red circles represent the ideal behavior of Pmax.

The DSSCs manufactured in this work displayed electrical performance as reported in the literature [2, 9, 22]. To improve the electrical performance, it is possible to optimize the fabrication parameters and selected materials that ensure the lowest internal resistance, facilitate the electrons flow, and increase the efficiency of electron injection. Furthermore, it is possible to increase the dye photostability and to reduce the electron recombination with the oxidized dye, and with the species of the electrolytic solution, as well as the electron recombination due to weak interaction of the dye and the conduction band of nanostructured TiO2 [5, 11, 19, 41-43].

4. CONCLUSIONS

The work presents the manufacture and characterization of DSSCs sensitized with plant dyes from Amazon Forest. Characterization studies by the UV-vis spectroscopy made it possible to know the absorption spectra of each plant dye and the XRD technique allows the structural characterization of the nanostructured semiconductor layer. On the other hand, electrical characterization allowed us to obtain the efficiency parameters of the respective solar cells for each dye. Experimental results showed the potential of the plant dyes extracted from Amazon Forest to respond to the demand for renewable energy sources specifically for low-cost solar cells.

ACKNOWLEDGMENTS

We would like to thank CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior), CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico) and FAPEAM (Fundação de Amparo à Pesquisa do Estado do Amazonas) for financial support.

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Publication Dates

  • Publication in this collection
    24 May 2021
  • Date of issue
    2021

History

  • Received
    15 June 2020
  • Accepted
    11 Feb 2021
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