A straightforward comparison between QDSSCs and DSSCs.
Abstract
The need to produce renewable energy with low production cost is indispensable in making the dream of avoiding undue reliance on non-renewable energy a reality. The emergence of a third-generation photovoltaic technology that is still in the infant stage gives hope for such a dream. Solar cells sensitized by dyes, quantum dots and perovskites are considered to be third-generation technological devices. This research focuses on the development of suitable and reliable sensitizers to widen electromagnetic (EM) wave absorption and to ensure stability of the photovoltaic system. This article discusses the basic principles and the progress in sensitized photovoltaics.
Keywords
- third-generation solar cells
- sensitized solar cells
- dye-sensitized solar cells
- quantum dot-sensitized solar cells
- perovskite-sensitized solar cells
1. Introduction
Third-generation photovoltaics are able to produce high efficiency photon to electricity conversion devices at a cheaper production cost. Solar cells based on pure Si forms were the first-generation devices with an efficiency of ~27%. Due to the high production cost, researchers searched for new processes and materials that led to the second-generation solar cells comprising copper indium diselenide, amorphous silicon, and polycrystalline solar cells. Production was still expensive, as the fabrication process required a large amount of energy. Production of the third-generation solar cell is cheaper and the cells are reasonably efficient. There are several technologies classified as third-generation solar cell technologies. These include solar cells sensitized by a dye material, solar cells sensitized by quantum dots (QDs) and perovskite-sensitized solar cells. These solar cells have a similar structure consisting of a photoanode, counter electrode (CE) and a medium for charge transport. The working principle is also similar. Work on sensitized photovoltaics started during the 1970s with the use of organic dyes as the sensitizer. Organic dyes can be natural or synthetic. Natural organic dyes can be obtained from plant sources but the performance is poor and the efficiency is low. Apart from natural organic dyes, synthetic organic dyes can give efficiency as high as 13%. Ruthenium based dye is one of the synthetic organic dyes and is known to give good performance with current density about 20 mA cm-2. As development in dye-sensitized solar cells (DSSCs) continues, an idea to replace organic dyes with inorganic sensitizers resulted in the emergence of quantum dot-sensitized solar cells (QDSSCs) that utilize quantum dots or nano-sized semiconductor crystals with a short band gap and a high extinction coefficient. Later, since 2009, researchers have begun to use perovskite materials as sensitizers. Perovskite works very well with the solid-state hole transfer material and until now its efficiency has reached 21%. However, perovskites are very moisture-sensitive materials and fabrication must be done in very clean and controlled conditions. In sensitized solar cells, the photoanode is a very crucial component because this is where the electrons are generated by the sensitizer. Photoanodes will absorb photons, excite and transport electrons when illuminated. On exiting the photoanode, the electrons will be sent to the cathode and returned to the sensitizer via a hole conductor or a redox mediator in the electrolyte. For DSSCs, the photoanode components are the dye sensitizer, a mesoporous semiconducting oxide layer and a transparent conducting oxide (TCO). Photoanodes for QDSSC and perovskite solar cells have similar components with DSSCs except that quantum dot nano-sized semiconductor crystals and perovskite materials act as the sensitizer. Another difference between them is the redox mediator used in the electrolyte. QDSSC works well with the polysulphide electrolyte instead of the iodide based electrolyte (as in DSSCs) because the iodide-based electrolyte will cause rapid degradation in photocurrent due to the corrosive nature of the iodide ion on many semiconductor materials including quantum dots. Perovskite solar cells use hole conductors instead of a redox mediator electrolyte. Figure 1 illustrates progress of third-generation devices.
2. Dye-sensitized solar cells (DSSCs)
DSSCs employ oxide semiconductors with wide band gaps and sensitizers that absorb electromagnetic (EM) waves in the visible light. DSSC was first developed in 1972 as a chlorophyll-sensitized zinc oxide (ZnO) electrode solar cell [1]. In 1976, an amorphous silicon photovoltaic was reported for the first time by Carlson and Wronski, and its efficiency was 2.4% [2]. Subsequently, solar energy researchers began to give attention to DSSCs. However, the main dilemma was that a single layer of dye molecules on the surface allowed only 1% incident sunlight absorption that delayed further progress [3]. The breakthrough in DSSC research was in 1991 [4]. The efficiency was 7.1%. About 80% of photons absorbed were converted into electrical current. The cheap cost of production and the simple structure inspired many researchers worldwide to improve the efficiency to a level deemed acceptable for commercialization.
The DSSC operating principle may be compared to the process of photosynthesis with the dye functioning as chlorophyll [4]. In DSSCs, the transport of charges (electrons) to the external circuit begins when electrons exit the semiconducting network layer and ends when the redox mediator in the charge transport medium returns them to the sensitizers. The purity of the semiconducting material is not as crucial as in the earlier generation solar cells.
2.1. DSSC structure
Figure 2 shows the structure of a DSSC. The photoanode consists of a TCO substrate on the top of which is deposited a semiconducting oxide layer (usually TiO2) and the dye sensitizer. Actually, there are two TiO2 layers. The first TiO2 layer is a blocking layer to suppress electron recombining with the ionized dye and/or the mediators. The second layer is mesoporous TiO2 of 20–30 nm thickness. These particles are larger than the blocking layer particles. The mesoporous TiO2 layer thickness is about 10 µm. A colloidal TiO2 paste for the second layer can be prepared by grinding TiO2 of 21 nm size with nitric acid, a polymer of low molecular mass (e.g. polyethylene glycol of molecular mass 200 g/mol) with a little surfactant. This paste will be deposited over the blocking TiO2 layer and heated at ~450°C for 30 min. To ensure the dye adheres to the mesoporous TiO2 layer, the TiO2 films are soaked in the dye solution overnight. The larger surface area of the mesoporous TiO2 area allows a greater amount of dye to be adsorbed on its surface. An electrolyte usually with an iodide/triiodide couple is needed for DSSC. The electrolyte can be in liquid or gel form. A catalytic active material (usually platinum) is required as the counter electrode to reduce the triiodide ion (
2.2. Working principle of DSSCs
Figure 3 shows the energy levels in the working of a DSSC. The Fermi energy level of TiO2 will be aligned with the redox energy level when there is no light. Upon illumination, dye molecules (
Here,
The transferred electrons percolate through the interconnected nanocrystalline TiO2 network to the conducting substrate within milliseconds (10−3 s). For good performance of the DSSC, this process has to be completed with the recombination reaction displayed in Eqs. (3) and (4).
Eq. (3) describes electron recombination with the ionized dye molecule and Eq. (4) describes electron-triiodide ion recombination. Electrons exit the TCO substrate and travel towards the counter electrode through the external circuit and reduce a triiodide ion in the electrolyte to an iodide ion as shown in Eq. (5).
The iodide ion diffuses to the photoanode and is oxidized back to a triiodide ion regenerating the dye molecule in the process. This process occurs continuously as shown in Eq. (6).
2.3. Dye sensitizer
The dye sensitizer is one of the important components of the DSSC. It works as an absorber of light and produces electrons. For good light conversion into electricity, the dye or sensitizer must have the following:
A broad absorbance spectrum of solar light for high photocurrent.
Anchoring groups such as carboxylate for attachment on the TiO2 surface so that electron transfer can occur from the LUMO of the dye to the TiO2 CB.
In order for the electrons to be transferred to the oxidized dye molecules efficiently for dye regeneration, the redox level has to be at more negative potential than the HOMO potential of the dye. The LUMO has to be less positive compared to the TiO2 CB for electron injection.
The dye covering the TiO2 surface should not stack on each other.
2.3.1. Ruthenium sensitizer
Desilvestro et al. [5] was the first to report the use of ruthenium complex tris(2,2′-bipyridyl-4,4′-di-carboxylate)ruthenium(II) dichloride dye in DSSC. The percentage conversion of absorbed incident photons to current (IPCE) for this DSSC was 44%. In 1991, O’Regan and Grätzel, reported IPCE of more than 80% from a DSSC using [Ru(2,2′-bipyridine-4,4′-dicarboxylicacid)2(μ-(CN)Ru(CN) (2,2′-bipyridine)2)2] dye adsorbed on a mesoporous, nanocrystalline TiO2 surface. The electrolyte contained
The N3 dye was almost no match in terms of charge transfer ability until Nazeeruddin et al. [9] developed the triisothiocyanato-(2,2′:6′,6″-terpyridyl-4,4′,4″-tricarboxylato) Ru(II) tris(tetrabutylammonium) or ‘black dye’ and coded as N749. The DSSC with black dye showed a broader IPCE spectrum in the visible region compared to N3. The overall efficiency obtained for this DSSC with black dye was 10.4% under 1 Sun illumination [10].
The substitution of two protons in the carboxyl group of N3 dye with tetrabutylammonium cations resulted in [Bu4N]2[Ru(4-carboxy-4-carboxylate-2,2′bipyridine)2(NCS)2] or N719 dye. This dye exhibits a higher efficiency than N3 dye [11]. The higher efficiency is related to the higher Voc that resulted from the upshift of the TiO2 Fermi level. However, the performance of DSSC using N719 dye is still lower than the N749 since N719 does not absorb in the red. To extend the EM absorption region, the dye can be tuned. This can be accomplished by introducing a π* molecular orbital ligand and by using a strong donor ligand to destabilize the metal t2g orbital [12]. By achieving this, the absorption range can be stretched from visible to the near infrared region. Islam et al. [12] have synthesized ruthenium complexes containing 2,2′-biquinoline-4,4′-dicarboxylic acid where the π* orbital is lower or at a more positive potential than that containing 2,2′-bipyridine-4,4′-dicarboxylic acid. The DSSC using this sensitizer exhibited lower efficiency due to the dye excited state being at a more positive potential than the CB of TiO2. This led to reduced electron injection driving force and lowered the photocurrent. The nanocrystalline TiO2 soaked in [Bu4N]2[cis-Ru(4-carboxy-2-[2′-(4′-carboxypyridyl)]quinoline)2(NCS)2] has been investigated by Yanagida et al. [13]. They found that the IPCE spectrum extended up to 900 nm. Unfortunately, the maximum IPCE value obtained for this dye is lower (~40%) compared to the N719 (~80%). This is due to the lower LUMO which is 0.24 V below that of N719.
2.3.2. Porphyrin sensitizer
The porphyrin sensitizer also requires a binding group such as carboxylic acid and 8-hydroxylquinoline (HQ) to adsorb efficiently the TiO2 semiconductor [14]. The linkers containing carboxylic acid or HQ can be located at
Kay and Grätzel were the first to report on DSSC using copper porphyrin [15]. The overall efficiency was 2.6%. The development of porphyrin sensitizers for SSCs gained more attention when Wang et al. [16] reported an efficiency of 5.6% under AM 1.5 illumination using zinc-porphyrin as the sensitizer with the co-adsorbent chenodeoxycholic acid (CDCA). The efficiency was increased to 7.1% reported by the same group for the zinc-porphyrin sensitizer with the aryl group as the electron donor and malonic acid as the acceptor ,which is shown in
Figure 6 [17]. Since then, the research on development of the porphyrin sensitizer increased rapidly. Park et al. [18] have shown that electron injection can be enhanced using two equivalent π-conjugated malonic acid linkers at the
The serious dye aggregation problem for porphyrins on TiO2 films compared with the ruthenium complexes led to poor DSSC efficiency. The problem was solved by introducing long alkyl chains and 3,5-di-tert-butylphenyl groups to the porphyrin ring at the
To further improve the performance of porphyrin based DSSC, light harvesting has to be enhanced which means the HOMO and LUMO energy gap must be decreased. There are two approaches: (1) to fuse or dimerize porphyrins and (2) by coupling a chromophore to the porphyrin ring. Eu et al. [22] have fused two quinoxaline derivatives to the zinc porphyrin to form 5,10,15,20-tetrakis(2,4,6-trimethylphenyl)-6′-carboxyquinoxalino[2, 3-
The introduction of a highly conjugated π-extended chromophore at the
2.3.3. Non-metallic organic dyes
Metal free or non-metallic organic dyes have been studied intensively to replace ruthenium-based sensitizers in DSSC. The metal free organic dyes have a molar extinction coefficient that is usually higher than Ru complexes [27–29]. Metal free dyes have opto-electronic properties that are easily tuned and they are cheaper to produce [30]. The general design principle for dye sensitizer is shown in Figure 7.
In general, organic dyes can be grouped as neutral and ionic organic dyes. Examples of neutral organic dyes are coumarins, triphenylamine, phenothiazine and indoline. Examples of ionic organic dyes are squarylium, cyanine, hemicyanine and merocyanine.
Tian et al. [31] have synthesized organic dyes with phenothiazine (PTZ) as the electron donor and rhodamine-3-acetic acid or cyanoacrylic acid as the electron acceptor. The DSSC utilizing the dye with cyanoacrylic acid as the anchoring acceptor exhibited 5.5% efficiency. Marszalek et al. [32] reported two novel organic dyes. The dyes comprised of electron donating 10-butyl-(2-methylthio)-10
Coumarin-based dye is a promising sensitizer for DSSC because it has good photoelectric conversion properties [33]. Wang et al. [33] reported that a DSSC using coumarin dye, 2-cyano-3-(5-{2-[5-(1,1,6,6-tetramethyl-10-oxo-2,3,5,6-tetrahydro-
3. Quantum dot-sensitized solar cells (QDSSCs)
As the research on DSSCs progressed, the idea of replacing dyes with QDs emerged. QDs are nano-dimensional structures with a narrow band gap suitable for absorbing light in the visible region. Therefore, when deposited over the mesoporous TiO2 layer, the excited electrons in the QDs can be transferred to the mesoporous TiO2. Research on sensitization of a wide band gap semiconductor by using a narrow band gap material such as dye started during the 1960s, but QDs was used for wide band gap semiconductor sensitization for the first time in 1986 by Gerischer et al. [34]. Advancement in research on sensitization led to DSSCs. Based on the highly porous TiO2 DSSCs introduced by O’Regan and Grätzel [6], QDs were introduced to replace the dye [35–37]. Until now, a lot of research has been geared towards improving QDSSCs performance. The highest efficiency recorded is now around 9% [38, 39].
There are several advantages of inorganic QDs over organic dyes. This is because inorganic QDs are easy to produce and durable [40]. Moreover, the optical band gap of QDs is tuneable [41]. Another special property of QDs is the production of at least two electron-hole pairs per photon with hot electrons. This is due to the impact of ionization in the QD nano-sized semiconducting material [42]. QDs can also reduce dark current and in doing so improve working of the photovoltaic system. This is because the extinction coefficient of QDs is high [43]. The theoretical efficiency for QDSSCs calculated by considering carrier multiplication due to impact of ionization was 44.4% [44].
QDSSCs and DSSCs have a lot of similarities and some differences. The major difference between these two is the sensitizer. QDSSCs utilize nano-sized semiconductor QDs and DSSCs utilize light absorbing dye. Another difference is material conformity. Some materials that worked effectively in DSSCs are not compatible with QDSSCs and could give a bad impact on the performance of the cells. Table 1 compares the components for DSSCs and QDSSCs.
Component | QDSSCs | DSSCs |
---|---|---|
Sensitizer | Sensitizer used is inorganic quantum dots such as CdSe, CdTe, CdS, etc. |
Sensitizer include organic dye such as ruthenium based dye, natural dye, etc. |
Wide band gap semiconductor | A lot of work on QDSSCs utilized TiO2 as the one of photoanode components |
A lot of work on DSSCs utilized TiO2 as one of the photoanode components |
Electrolyte | Works on QDSSCs, employs the polysulphide redox mediator in the electrolyte due to its stability towards quantum dot | Works on DSSCs employs the iodide based redox mediator in the electrolyte due to its stability towards DSSCs performance |
Counter electrode | Metal chalcogenides | Platinum |
3.1. QDSSC structure
Although progress has been made, the efficiency value of QDSSCs has not surpassed that of DSSCs, which is 13% [26]. There is still a lot of improvement to be done in obtaining a better material for QDSSCs. Figure 8 illustrates schematically the QDSSC device and its components.
3.1.1. Photoanode
In works concerning QDSSCs, very frequently TiO2 was utilized as the wide band gap semiconductor compared to other oxides. Out of the many QDs chalcogenides, cadmium chalcogenides (CdS, CdSe and CdTe) are most popularly used in QDSSCs [45–47]. Another important component in QDSSC photoanodes is the passivation layer. The passivation layer prevents electron recombination that can improve performance of QDSSCs since the short circuit current density will not be reduced.
Chalcogenides of cadmium can easily be fabricated and have a tuneable band gap that can be achieved by controlling their size [45, 48–50]. CdS, CdSe and CdTe chalcogenide QDs have a band gap 2.3, 1.7 and 1.4 eV, respectively. Hence, incident light in the visible wavelength can be absorbed up to ~540 nm for CdS, ~731 nm for CdSe and ~887 nm for CdTe. Figure 9 shows the valence band (VB) and conduction bands of cadmium chalcogenide QDs and TiO2.
The use of two species of QDs in a single QDSSC has proven to enhance the efficiency, for example, CdS/CdSe, CdTe/CdSe and CdTe/CdS combinations were used as sensitizers [43, 51, 52]. When CdS and CdSe make contact with each other, electron redistribution will occur resulting in the CdS and CdSe band edge to shift to more or less positive potentials, respectively. The shifting of the band edge is referred to Fermi level alignment [43]. This process affects electron injection. The same process also happens in the combinations of CdTe/CdSe and CdTe/CdS. Figure 10 shows how CdTe/CdSe and CdS/CdSe combinations produce an effective electron injection. Application of co-sensitizing QDs in QDSSCs has shown excellent performance compared to QDSSCs fabricated with a single QD sensitizer [43, 51, 52].
Although tuning band gap with the size of the QDs is promising in enhancing performance of QDSSCs, this may give rise to stability problem [53]. To avoid this, alloyed cadmium chalcogenide QDs (AB
Even though QDs have many advantages as a sensitizer compared to organic dyes, the efficiency recorded for QDSSCs is still lower compared to DSSCs. Excited electrons in QDs can take one of three possible routes which are: (1) jump into the TiO2 conduction band which will be beneficial to the performance of the QDSSCs, (2) relax into the valence band by emitting energy and finally (3) combine with redox mediator ions (recombination process) in the electrolyte which are routes detrimental to the QDSSC performance. To overcome recombination, researchers have QDs coated on the surface with ZnS, SiO2 and amorphous TiO2 (am-TiO2) [38, 56, 57]. Ren et al. [38] have introduced a novel strategy to overcome recombination by implementing three passivation layers am-TiO2/ZnS/SiO2 resulting in 9% efficiency. Yang et al. [39] utilized the CdS layer as a passivation layer to the CdSeTe QDs and achieved 9.4% efficiency.
3.1.2. Electrolyte
Another important component in QDSSCs is the electrolyte. The electrolyte in QDSSCs functions as a charge carrier transporter between the photoanode and the counter electrode done via the redox mediators. The redox species in the electrolyte are also responsible for turning the oxidized QD species by donating an electron to the QDs. In QDSSCs, polysulphide electrolytes with
Due to problems that arise from utilization of liquid electrolytes such as leakage and easy vaporization, researchers have begun to use polymer electrolytes. However, the performance of QDSSCs based on the solid polymer electrolyte [62, 63] is low compared to QDSSCs fabricated with liquid electrolytes. This is because solid state electrolytes suffer from low ionic conductivity. Another alternative to the liquid electrolyte is to use gel polymer electrolytes (GPEs). GPE is very competitive since GPE based QDSSC performance is comparable with QDSSCs fabricated with the liquid electrolyte [64–66]. Kim et al. [65] successfully fabricated CdSe/CdS GPE based QDSSCs with 5.45% efficiency, which is comparable with QDSSCs based on the liquid electrolyte. As the GPE based QDSSCs is comparable with QDSSCs fabricated with the liquid electrolyte, utilization of GPE in QDSSCs will be an advantage in terms of providing stability and overcoming problems that arise from liquid electrolytes.
3.1.3. Counter electrode
The counter electrode is another important component in QDSSCs. Electrons from the photoanode are returned to the QD when the electrons react with the redox ions in the electrolyte. In DSSCs, platinum (Pt) is the best material to be used as the CE due to its high stability and high catalytic activity for the triiodide ion to be reduced into the iodide ion. However, Pt CE does not work for QDSSCs. This is because Pt [67]:
is not catalytic to the sulphide ion,
restrains the charge transfer to polysulphide ions and
can react with sulphur.
Hence, researchers look for alternative materials to be used as the CE such as noble metals, carbon based materials and metal chalcogenides [68]. The highest efficiency are presently exhibited by QDSSCs utilizing copper sulphide (Cu2S) as the CE (
3.2. Working principle of QDSSC
Basically, QDSSCs working mechanism is identical with DSSCs. TiO2 is used in the photoanode. Upon light incident, the QD sensitizers absorb photons to excite electrons into its CB (photoexcitation). Electrons in the CB of QDs will be injected to the CB of TiO2 and oxidized QDs will be regenerated by receiving electron from
As the above process continues, electrons will keep moving through the cell and current is produced. Figure 11 shows the working mechanism of QDSSCs where only electron movement is shown. Red arrows in Figure 11 indicate the electron movement.
4. Perovskite-sensitized solar cell
Perovskite is a term for materials that have a similar crystal structure to calcium titanium oxide (CaTiO3), that is, ABX3 where A and B are cations and X is an anion. A is typically a large cation, such as ethylammonium (CH3CH2NH3+) [70], formamidinium (NH2CH═NH2+) [71] and methylammonium (CH3NH3+) [72]. B is a cation metal of carbon family, such as Ge2+, Sn2+ and Pb2+ and anion X is a halogen (F, Cl, Br and I).
Perovskite cells are typically fabricated with two structures which are mesoporous and planar structures.
4.1. Mesoporous structure
The mesoporous structure consists of a transparent conducting oxide (TCO) substrate coated with an oxide semiconductor compact layer, mesoporous metal oxide (e.g. TiO2, Al2O3), perovskite sensitizer, hole conductor and gold conductor.
Kojima et al. [73] reported the first perovskite material (CH3NH3PbBr3 and CH3NH3PbI3) used as a sensitizer in photoelectrochemical cells. The cell consists of mesoporous TiO2 film having 8–12 µm thickness, iodide/triiodide redox couple liquid electrolyte and platinum counter electrode. The band gap CH3NH3PbBr3 is 1.78 eV and that of CH3NH3PbI3 is 1.55 eV. They have reported that the solar cells using CH3NH3PbBr3 and CH3NH3PbI3 sensitizers exhibit the efficiencies of 3.13 and 3.81%, respectively. TiO2 sensitized with orthorhombic (CH3CH2NH3)PbI3 has been reported by Im et al. [70] to have an optical band gap of 2.2 eV. The cell using the (CH3CH2NH3)PbI3 sensitizer and the electrolyte with the iodide/triiodide redox mediator exhibits an efficiency of 2.4%. Based on the work done by Kojima et al. [73], Im et al. [74] have investigated the effect of TiO2 film thickness on perovskite photovoltaic performance. The cell with 8.6 µm thick TiO2 film exhibits an efficiency of 3.37% comparable with that of Kojima et al. [73]. The performance of the cell increases when the TiO2 film thickness decreases. The cell with 3.6 µm thick TiO2 film exhibits an efficiency of 6.2%. Unfortunately, the cell exhibited poor stability due to perovskite decomposition and degraded within minutes. In 2012, the stability of CH3NH3PbI3-sensitized solar cell over 500 h has been reported by Kim et al. [72]. They have substituted the liquid electrolyte that was previously tried by Kojima et al. [73] with a solid state hole transport layer (
Lee et al. [75] have constructed a meso superstructure (
Figure 12b) of an organometal halide perovskite solar cell. This structure can be obtained by controlling the perovskite precursor concentration. The cell consists of mesoporous n-type TiO2, CH3NH3PbI3Cl and p-type
4.2. Planar structure
The planar perovskite solar cell architecture is similar to the mesoporous structure except for the mesoporous metal oxide.
Lee et al. [75] have shown that the perovskite photovoltaic system can still function without the non-blocking TiO2 layer. Hence, the planar p-i-n and the p-n junction perovskite structures are possible to construct.
Figure 13 shows an example of the p-i-n junction perovskite solar cell, which consists of an n-type compact metal oxide thin layer, intrinsic perovskite layer and p-type HTM layer. This structure has been demonstrated by Liu et al. [79] using n-type TiO2 compact layer, perovskite CH3NH3PbI3-xClx and p-type
4.3. Lead free perovskite solar cell
Perovskite cells have shown a high efficiency of 21%. The perovskite material is very absorptive and moisture sensitive. The main problems are stability and lifetime. Perovskite solar cells are even less stable than organic polymer photovoltaics. Lead is also poisonous and has to be substituted by some other friendlier materials, like Sn. These are among the main challenges faced by researchers. The absorption of tin halide perovskite has been reported up to 1000 nm [82]. By partially substituting lead with tin (CH3NH3Sn
5. Summary
The third-generation-sensitized solar cells have proved that they have the potential to compete with the conventional silicon based photovoltaics. The use of cheap materials with high performance make third-generation-sensitized solar cells a bright candidate as a future photovoltaic technology compared to other third-generation solar cells. The sensitized photovoltaic started with the emergence of DSSC using mesoporous nanocrystalline TiO2 sensitized with the ruthenium based dye molecule. Since then, the molecular engineering of the dye molecules are extensively studied to improve the DSSC performance. The sensitizer used in the photovoltaic device evolved from organic (dye) to inorganic (quantum dot) and hybrid organic-inorganic (perovskite) sensitizer. The tuneable energy band gap of quantum dots enables them to produce multiple electron-hole pairs per photon. The progress in the performance of perovskite solar cells is very promising. In the beginning, the efficiency of the perovskite solar cell was less than 4%. The efficient reached around 20% within less than 10 years. However, the stability and toxicity issues of lead have to be solved before they can be commercialized. Tin-based perovskite solar cell is already under investigation to replace the toxic lead.
Acknowledgments
Authors thank University of Malaya, Malaysian Ministry of Higher Education (MOHE) and Malaysian Ministry of Science, Technology and Innovation (MOSTI)
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