Hindawi
International Journal of Photoenergy
Volume 2017, Article ID 2704864, 5 pages
https://doi.org/10.1155/2017/2704864
Research Article
Performance Enhancement of Dye-Sensitized Solar Cells
Using a Natural Sensitizer
Zainal Arifin,1,2 Sudjito Soeparman,1 Denny Widhiyanuriyawan,1 and Suyitno Suyitno2
1
Department of Mechanical Engineering, Brawijaya University, Jl. Veteran, Malang 65145, Indonesia
Department of Mechanical Engineering, Sebelas Maret University, Jl. Ir. Sutami 36 A, Surakarta 57126, Indonesia
2
Correspondence should be addressed to Zainal Arifin; zainal arifin@staff.uns.ac.id
Received 26 October 2016; Revised 22 December 2016; Accepted 29 December 2016; Published 24 January 2017
Academic Editor: K. R. Justin Thomas
Copyright © 2017 Zainal Arifin et al. This is an open access article distributed under the Creative Commons Attribution License,
which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Dye-sensitized solar cells (DSSCs) based on natural sensitizers have become a topic of significant research because of their urgency
and importance in the energy conversion field and the following advantages: ease of fabrication, low-cost solar cell, and usage
of nontoxic materials. In this study, the chlorophyll extracted from papaya leaves was used as a natural sensitizer. Dye molecules
were adsorbed by TiO2 nanoparticle surfaces when submerged in the dye solution for 24 h. The concentration of the dye solution
influences both the amount of dye loading and the DSSC performance. The amount of adsorbed dye molecules by TiO2 nanoparticle
was calculated using a desorption method. As the concentration of dye solution was increased, the dye loading capacity and power
conversion efficiency increased. Above 90 mM dye solution concentration, however, the DSSC efficiency decreased because dye
precipitated on the TiO2 nanostructure. These characteristics of DSSCs were analyzed under the irradiation of 100 mW/cm2 . The
best performance of DSSCs was obtained at 90 mM dye solution, with the values of 𝑉oc , 𝐽sc , FF, and efficiency of DSSCs being
0.561 V, 0.402 mA/cm2 , 41.65%, and 0.094%, respectively.
1. Introduction
Performance of dye-sensitized solar cells (DSSCs) is influenced by semiconductors, electrolytes, transparent conductive oxide (TCO) substrates, counter electrode, and dye
sensitizers [1–6]. Dye plays an important role in the performance of DSSCs [7–9]. When synthetic dye such as
ruthenium complex is used as a sensitizer in a wide-bandgap
semiconductor, the DSSC efficiency becomes over 10% [3].
Because of high costs, presence of heavy metals, and complex
synthesis processes of synthetic dyes, natural dyes obtained
from leaves, fruits, and plants are a cheaper option and they
are nontoxic and completely biodegradable also [10].
Performance of DSSCs based natural sensitizer can be
enhanced by using chlorophyll. When ethanol is used as a
solvent, the efficiency of DSSCs improves to 36.11% compared
to that achieved when distilled water is used [10]. The acidity
of chlorophyll solution can be controlled to pH 3.5 by adding
benzoic acid, which helped increase the efficiency of DSSCs
from 0.07% to 0.28% [11]. The amount of dye molecules
that can be absorbed by the semiconductor is also essential
in improving the performance and the electron injection of
DSSCs [12]. High electron injection from photoexcited sensitizers to the conduction band of semiconductors strongly
influences the current density of DSSCs [1].
The amount of dye adsorbed by semiconductors can be
studied by controlling the size of the semiconductor and
modifying the morphological structure of the semiconductor
[12–16]. The properties of the dye solution can also affect
the amount of dye molecules adsorbed by semiconductors
[17]. One of the solution’s properties that can be easily controlled is the concentration of the solution. The dye solution
concentration on the semiconductor is also important for
study because of its influence in DSSC performance. In this
work, the performance of DSSCs with natural chlorophyll
as the sensitizer at various concentrations was studied. The
performance of chlorophyll-based DSSCs was compared with
the results obtained using N719-based DSSCs.
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International Journal of Photoenergy
2. Material and Method
2.2. DSSC Fabrication and Testing. The DSSCs were assembled as follows: fluorine-doped tin oxide (FTO, SigmaAldrich) conductive glasses were used as the substrate. The
semiconductor paste was prepared by dissolving 0.24 g TiO2
nanopowder (21 nm, Sigma-Aldrich) into 4 mL ethyl alcohol
(96%, Merck). The TiO2 paste was applied to FTO-coated
glass and flattened using the doctor blade method until the
TiO2 film becomes a homogenous layer. The semiconductor
layer was maintained at 20 𝜇m and an area of 1 × 1 cm2 . Then,
the TiO2 layer coated on the FTO substrate was sintered at
450∘ C for 2.5 h to enhance the bonding between the semiconductor and the FTO glass. After that, the photoelectrodes
were immersed in the respective dye solution for 24 h at
30∘ C.
The counter electrode was conducted by a sputtering process. The catalytic platinum was deposited on the FTO glass in
a vacuum tube at 9.5 × 10−5 Torr. The platinum material target
was connected to the negative terminal at a high voltage of
404 V and 125 mA, while the FTO glass was connected to the
positive terminal. The electrolyte solution was synthesized
by mixing 3.3 g sodium iodide (99.95%), 523.875 mg pure
iodine (99.95%), 5.481 g heteropolyacid (HPA), and 30 mL
acetonitrile. HPA added in the electrolyte act as an electron
acceptor to prevent recombination and photoreduction of
iodide (I− ) [18]. The electrolyte solution was injected into
the assembled DSSCs at 30 𝜇m intervals and sealed by glass
glue. The performance of DSSCs was determined by a solar
4.5
4
3.5
Absorbance
2.1. Chlorophyll Dye Synthesis. The chlorophyll dye extracted
from 100 g of papaya leaves was added to 1 L of ethyl alcohol
(96%, Merck, Germany) and heated at 70∘ C for 3 h. The
separation of this solution was performed using Buchner
funnel with single number 42 Whatman filter paper. The
extracted dyes were then isolated from the ethanolic solution
by rotary evaporation and got 8.5 g of crude chlorophyll.
The crude chlorophyll was added to petroleum ether until
a yellow color appears in the column chromatography. The
separation process was followed by replacing the eluent with
a solution of 10% diethyl ether in petroleum ether to produce
0.76 g (8.9%) chlorophyll (green), 0.035 g (0.41%) 𝛽-carotene
(yellow), 0.03 (0.35%) phycoerythrin (orange), and residues.
A detailed description of the synthesis of chlorophyll dyes
can be found elsewhere [11]. The chlorophyll was dissolved
in ethyl alcohol to obtain solution of various concentrations
(60, 70, 80, 90, and 100 mM). The synthetic dye used in this
research was 0.03 mM N719 (Dyesol). The optical properties
of the dyes were measured by UV-Vis spectroscopy (Lambda
25, Perkin Elmer). The functional groups in the dyes were
characterized by Fourier transform infrared spectroscopy
(FTIR, Shimadzu). Cyclic voltammetry (CV, Metrohm AG)
was used to determine the reduction and oxidation potentials
(𝐸red and 𝐸ox , resp.) of the dyes. The Pt wire, Pt plate, and
Ag/AgCl were used as a counter, working, and reference
electrodes, respectively. The potential applied in the CV
process was from −2.0 V to +2.0 V with a scan rate of
100 mV/s.
5
3
2.5
2
1.5
1
0.5
0
400
450
500
550
600
650
700
750
800
Wavelength (nm)
N719
60 mM
70 mM
80 mM
90 mM
100 mM
Figure 1: Absorption spectra of N719 and chlorophyll dyes.
simulator under irradiation of 100 mW/cm2 . The currentvoltage (𝐼-𝑉) curve was measured by a digital multimeter
(Keithley 2401) to obtain 𝐽sc , 𝑉oc , FF, and efficiency of
DSSCs.
3. Results and Discussion
3.1. Dye Characterization. The absorption spectra in the
visible light spectrum (400–700 nm) of N719 and chlorophyll
dyes are shown in Figure 1. The absorption peak of N719
can be seen at 515 nm and chlorophyll at 660 nm [11].
Variation in the chlorophyll dye solution concentration did
not affect the position of the absorption peak spectra but
affected the absorbance value at a wavelength of 660 nm.
This corresponds with the Lambert-Beer law, according to
which the absorbance of a solution is proportional to its
concentration at the same path length of the light beam [19].
Figure 2 and Table 1 show the cyclic voltammetry (CV)
test results of N719 and chlorophyll dyes. The electrochemical
oxidation and reduction onset potentials (𝐸ox and 𝐸red , resp.)
were used to calculate the energy levels of the highest occupied molecular orbital (𝐸HOMO ) and the lowest unoccupied
molecular orbital (𝐸LUMO ) [11]. The onset potentials were
determined from the intersection of tangents between the
rising current and the baseline charging current of the CV
curves. As shown in Table 1, the various concentrations have
a minor effect on 𝐸HOMO and 𝐸LUMO values of chlorophyll
dyes. Figure 3 shows the FTIR measurements of N719 and
chlorophyll dyes. All dyes display peaks in both the 2500–
3000 and 1600–1750 cm−1 region, corresponding to the presence of the –OH and C=O groups, respectively. However, the
N719 dye produced more C=O stretching and –OH groups
than chlorophyll dyes. In general, the concentration variation
in chlorophyll dyes did not change the C=O stretching and
–OH groups.
�International Journal of Photoenergy
3
Table 1: Energy levels of N719 and chlorophyll dyes.
Dyes
N719
60 mM chlorophyll
70 mM chlorophyll
80 mM chlorophyll
90 mM chlorophyll
100 mM chlorophyll
a
b
𝐸ox (V)
0.68
0.71
0.77
0.77
0.75
0.72
𝐸HOMO a (eV)
−5.08
−5.11
−5.17
−5.17
−5.15
−5.12
𝐸red (V)
−1.22
−0.76
−0.76
−0.78
−0.76
−0.70
𝐸LUMO b (eV)
−3.18
−3.64
−3.64
−3.62
−3.64
−3.70
𝐸Band Gap (eV)
1.90
1.47
1.53
1.55
1.51
1.42
𝐸HOMO = −𝑒[𝐸ox + 4.4].
𝐸LUMO = −𝑒[𝐸red + 4.4].
Table 2: Characteristics of DSSCs based on N719 and chlorophyll dyes.
Dyes
N719
60 mM chlorophyll
70 mM chlorophyll
80 mM chlorophyll
90 mM chlorophyll
100 mM chlorophyll
𝐽SC (mA/cm2 )
5.612
0.169
0.188
0.401
0.402
0.346
𝑉OC (V)
0.553
0.542
0.501
0.594
0.561
0.606
Dye loading (mol/cm2 )
1.0 × 10−7
5.7 × 10−8
8.4 × 10−8
9.8 × 10−8
1.1 × 10−7
1.3 × 10−7
𝜂 (%)
1.293
0.040
0.045
0.074
0.094
0.049
FF (%)
41.63
44.02
48.16
39.55
41.65
42.34
80
60
Carboxylic acids C–O
−0.15
Aliphatic amines C–N
−0.05
Aromatics C–C
Carbonyls C=O
0.05
40
20
Transmittance (%)
0.15
Alkanes
C –H
Phenols
O–H
100
−0.35
−2.5
1000
1250
1500
1750
2000
2250
2500
2750
3000
3250
3500
−0.25
3750
0
4000
Current density (mA/cm2 )
0.25
Wavenumber (cm−1 )
−1.5
−0.5
0.5
1.5
2.5
Potential (mV)
N719
60 mM
70 mM
80 mM
90 mM
100 mM
Figure 2: Cyclic voltammogram curves of N719 and chlorophyll
dyes.
3.2. Performance of DSSCs. Figure 4 and Table 2 show the
performance of DSSCs based on N719 and chlorophyll dyes
under irradiation of 100 mW/cm2 . The energy conversion
efficiency of N719 dye-based DSSCs was higher than all
chlorophyll dye-based DSSCs. The N719 dye-based DSSCs
achieved an efficiency of 1.293%, while the highest efficiency
of chlorophyll dye-based DSSCs was 0.094% at 90 mM.
The amount of dye loading on the semiconductor surface
was measured by the dye desorption method [12]. This
process was followed by the immersion of the TiO2 -dye
electrode in an ethanol solution of 0.1 M NaOH. The dye
desorption took place after 1 h, with the solution becoming
pink for the N719 dye and green for the chlorophyll dye. At
N719
60 mM
70 mM
80 mM
90 mM
100 mM
Figure 3: FTIR spectra of N719 and chlorophyll dyes.
the same time, the TiO2 electrode turned colorless because
it loses the dye on its surface [12, 20]. Figure 5 shows the
UV-Vis absorption spectra of the solutions measured to
estimate the concentration of the adsorbed dye molecules.
The concentration of the adsorbed dye was calculated by
using the Lambert-Beer law:
𝐴 = 𝜀 ⋅ 𝑐 ⋅ 𝑙,
(1)
where 𝐴 is the intensity of the UV-Vis absorption spectra at
the peak of N719 and chlorophyll dye in 515 and 660 nm,
respectively, 𝜀 is the molar extinction coefficient of dye, 𝑐
is the dye molecular concentration, and 𝑙 is the path length
of the light beam. The molar extinction coefficient of N719
determined to be 14,100 M−1 cm−1 at 515 nm [12, 21] and for
chlorophyll is 86,300 M−1 cm−1 at 660 nm [22].
�4
International Journal of Photoenergy
0.4
of 90 mM chlorophyll dye has good interaction with the
TiO2 surfaces, due to the high dye loading value without
producing the significant inactive dye precipitation effect.
Current density (mA/cm2 )
0.35
0.3
4. Conclusions
0.25
0.2
0.15
0.1
0.05
0
0.00
0.10
0.20
0.30
0.40
0.50
0.60
Voltage (V)
60 mM
70 mM
80 mM
90 mM
100 mM
Figure 4: 𝐼-𝑉 curves of DSSCs under irradiation intensity of
100 mW/cm2 .
Chlorophyll extracted from papaya leaves can be used as
a dye sensitizer in DSSCs. However, the energy conversion
efficiency is still lower than that of synthetic dye-based
DSSCs. The N719 dye-based DSSCs achieved an efficiency
of 1.293%, while the highest efficiency of chlorophyll dyebased DSSCs was 0.094% at 90 mM. The variation in the
chlorophyll dye solution concentration did not change the
HOMO-LUMO energy level and –COOH functionalities.
Increasing the dye solution concentrations also increased the
efficiency of DSSCs because of the increase in the amount
of dye adsorbed by TiO2 . However, at concentrations above
90 mM, the efficiency of DSSCs decreased because of the
precipitation of dye on the TiO2 nanostructure. This raises
the number of inactive dye molecules on the surface of TiO2 ,
preventing the electron injection processes in DSSCs.
1.8
Nomenclature
1.6
𝐴: Intensity of the UV-Vis absorption (—)
𝑐: Solution concentration (molar)
𝑙: Path length of the light beam (cm).
1.4
Absorbance
1.2
1
0.8
Greek Letters
𝜀: Molar extinction coefficient (M−1 cm−1 )
𝜂: Efficiency (%).
0.6
0.4
0.2
Competing Interests
0
450
500
550
600
650
700
750
800
Wavelength (nm)
N719
60 mM
70 mM
80 mM
90 mM
100 mM
The authors declare that they have no competing interests.
Acknowledgments
Figure 5: UV-Vis absorption spectra of the solutions containing
dyes detached from TiO2 electrode.
The authors thank the Rector of Sebelas Maret University
(UNS) and DP2M DIKTI for the financial support through
the research Grant Nr.632/UN27.21/LT/2016.
Increasing the concentration of chlorophyll dyes
increased the DSSC efficiency and was seen by the increase in
the current density (𝐽SC ). The rise in current density is associated with the amount of dye that can be adsorbed by the TiO2
electrodes [1]. However, at concentrations above 90 mM, the
dye loading value increased, while the efficiency of DSSCs
decreased. This result can be explained by the precipitation
of dyes on the TiO2 electrodes. Because of this phenomenon,
some dissolution of TiO2 by the acidic carboxylic groups
of the dye can occur. The resulting Ti+ ions form insoluble
complexes with chlorophyll dyes, causing precipitation of
these complexes in the pores of the film. This gives rise
to inactive dye molecules on the TiO2 surfaces [20, 23].
Based on this work, it has been found that the concentration
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