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Review

Perovskite Solar Cells: Progress and Advancements

School of Photovoltaic and Renewable Energy Engineering, University of New South Wales, Sydney 2052, Australia
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Authors to whom correspondence should be addressed.
Submission received: 26 August 2016 / Revised: 27 September 2016 / Accepted: 19 October 2016 / Published: 25 October 2016
(This article belongs to the Special Issue Selected Papers from 2nd Energy Future Conference)

Abstract

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Organic–inorganic hybrid perovskite solar cells (PSCs) have emerged as a new class of optoelectronic semiconductors that revolutionized the photovoltaic research in the recent years. The perovskite solar cells present numerous advantages include unique electronic structure, bandgap tunability, superior charge transport properties, facile processing, and low cost. Perovskite solar cells have demonstrated unprecedented progress in efficiency and its architecture evolved over the period of the last 5–6 years, achieving a high power conversion efficiency of about 22% in 2016, serving as a promising candidate with the potential to replace the existing commercial PV technologies. This review discusses the progress of perovskite solar cells focusing on aspects such as superior electronic properties and unique features of halide perovskite materials compared to that of conventional light absorbing semiconductors. The review also presents a brief overview of device architectures, fabrication methods, and interface engineering of perovskite solar cells. The last part of the review elaborates on the major challenges such as hysteresis and stability issues in perovskite solar cells that serve as a bottleneck for successful commercialization of this promising PV technology.

1. Introduction

Recent advances in organic-inorganic hybrid perovskite solar cells (PSCs) with methyl ammonium lead iodide as the archetypal material, have led to the advent of new low cost photovoltaic (PV) technology that could be a viable competitor to the commercially available Silicon based solar cells [1,2]. Apart from low cost, simple device processing and manufacturability combined compatibility with roll-to-roll processing and fabrication on flexible substrates add to the merits of the perovskite PV technology [3,4,5,6,7]. The term “perovskite” was attributed to the crystal structure of calcium titanate (CaTiO3), which was discovered by the German mineralogist Gustav Rose in 1839 and named in honour of the Russian mineralogist Lev Perovski [8]. The organic–inorganic hybrid halide based perovskites are widely studied in the 1990s for the application in transistor technology and light emitting diodes, due to their excellent opto-electronic properties and solution processability of these materials [9,10,11,12,13,14,15]. Organic–inorganic hybrid halide based perovskites are a group of materials with the general formula ABX3, where A is an organic cation (CH3NH3+ or NH2CH3NH2+), B is a divalent cation (Pb2+ or Sn2+) and X is a monovalent halide anion (I, Br, or Cl) [16,17,18].
Organic-inorganic hybrid halide based perovskites was first used in photovoltaics as a sensitizer replacing the dye pigment in Dye sensitized solar cells (DSSCs), which reported a 3.8% PCE in 2009 [19]. The devices employed liquid electrolyte as hole transporting layer (HTL), therefore gained little attention due to low efficiency and poor stability. Later, the liquid electrolyte was replaced by solid-state HTL (Spiro-OMeTAD), which resulted in a solid-state device with relatively high efficiency, ~9%, in 2012. This breakthrough led to the so-called “perovskite fever” [20] attracting much research interest in the following years, eventually increasing the efficiency to a record 22.1% [21] in early 2016. The trend in increase of performance efficiency of perovskite solar cells along with the associated timeline is shown in Figure 1 and the corresponding device details are depicted in Table 1.
The stride of progress has been extraordinary and unprecedented in PV history and can be ascribed to numerous factors related to inexpensive fabrication costs, ease of processing, and the excellent electronic and optical properties of the perovskite materials. Moreover, the superior performance of the PSCs is reflected in their high open circuit voltage (Voc). The solar cell device efficiency (η) is generally defined as η = Jsc (short circuit current density) × Voc (open circuit voltage) × FF (fill factor). According to detailed balance theory, [31] the maximum open circuit voltage (Voc-max) of a semiconductor absorber is approximately its bandgap energy (Eg) subtracted/reduced by 0.25 eV and the ratio of Voc-max/Eg indicates the efficacy of the semiconductor material as a solar cell absorber. In line with this, the maximum theoretical limit (SQ-limit) calculated for the perovskite solar cells employing CH3NH3PbI3-xClx absorber (Eg ~1.55 eV) is as follows: Jsc(SQ-limit) is 27.20 (mA/cm2), Voc(SQ-limit) is 1.28 V, FF(SQ-limit) is 90.2 and PCE(SQ-limit) is 31.4% [32]. It clearly indicates that perovskite solar cells have immense potential for further development and the progress is promising [1,33,34,35,36].

2. Crystal Structure

The crystal structure of perovskites (ABX3), typically consists of a unit cell with five atoms in a cubic structure (α phase), in which the cation A has twelve nearest neighbouring anions X and the cation B has six as shown in Figure 2a. Under ideal conditions, in order to maintain high-symmetry cubic structure, the tolerance factor t should be close to 1. The tolerance factor t is expressed as a function of ionic radii of A, B and X site ions, which is written as
t = ( R A + R X ) { 2 ( R B + R X ) }
where RA, RB, and RX are the ionic radii of the corresponding ions. Larger the deviation from the ideal value t, the crystal structure will be distorted and the symmetry would be lowered. Therefore, in order to satisfy the ideal tolerance factor (t ≈ 1), the A-site ion must be much larger than the B-site ion. In the case of halide perovskites, in general, large Pb or Sn atom occupies the B site; hence the cation at A-site must be extremely large. At finite temperature, cubic structure may exist when t lies between 0.89 and 1, and smaller t (i.e., t < 0.89) could result in lower-symmetry tetragonal (β phase) or orthorhombic (γ phase) crystal structures. On the other hand, larger t (i.e., t > 1), could undermine the three-dimensional (3D) B–X network, leading to a two-dimensional (2D) layer structure. It is noteworthy to mention that the DFT calculations computed at zero temperature have revealed that the orthorhombic (γ phase) is the most stable and the cubic (α phase) is the most unstable structure, since it is very difficult to satisfy the ideal condition t = 1. However, transitions between those crystal structures often occur in most perovskites at finite temperature [37,38,39]. The tolerance factors of some of the notable hybrid perovskite materials are shown in Figure 2c.
The perovskite material (CH3NH3PbI3) undergoes reversible phase transition as a function of temperature [43]. At low temperature of about 100 K, a stabilized orthorhombic (γ) phase exists and the phase transition between the tetragonal (β) phase and orthorhombic (γ) phase occurs at around 160 K. The crystal structure for three phases is shown in Figure 2a–c. The tetragonal-cubic phase transition partially influences the thermal stability issue for MAPbI3 based PSCs [44]. In the case of formamidinium iodide (HC(NH2)2PbI3) based perovskites, a similar phase transition occurs at higher temperature, hence it is relatively stable compared to MAPbI3. A recent report revealed light soaking could also induce reversible structure transformation in halide perovskite materials [45].

3. Electronic Structure of Perovskites

The electronic structure of hybrid perovskites especially near the band edge is predominantly dictated by the BX6 (octahedra) building blocks. For instance, in the case of [PbI6]4− units in particular, the valence band (or highest occupied molecular orbital, HOMO) is determined by the Pb 6s–I 5p σ-antibonding orbital. Similarly, the conduction band (or lowest unoccupied molecular orbital, LUMO) is determined by the Pb 6p–I 5p π-antibonding and Pb 6p–I 5s σ-antibonding orbitals [46,47,48,49,50,51]. The unusual electronic properties of hybrid perovskites is mainly ascribed to the lone pair of s electrons in Pb cation, i.e., unlike most cations whose outer s orbitals are empty, Pb has an occupied 6s orbital, which lies below the top of the valence bands [52,53]. The valence band maximum (VBM) has strong Pb s and I p antibonding character, whereas the conduction band minimum (CBM) is mostly contributed from the Pb p state, which attributes to the unique dual nature (ionic and covalent characteristics) of electronic structures in halide perovskites. Figure 3 (top) shows the atomic structure of perovskite (ABX3) and the contribution of each of its atoms/ions towards the electronic structure of the perovskite material. In the hybrid perovskite structure of MAPbI3, the iodine ions at the X-site forms the valence band and the lead (anion) at the B-site forms the conduction band, while organic cation at the A-site remains electronically inactive but contributes to the structural stability and tolerance factor of the perovskite structure.
The contributions of MA, Pb, and I on the density of state of MAPbI3 perovskite are shown in Figure 3a (bottom). It can be clearly seen that the grey coloured distribution pertaining to the A cation lies well below the valence band maximum (VBM), therefore does not contribute to the bandgap electronically. The uniqueness of the electronic structure of the halide perovskites is also shown in Figure 3b–d, comparing with 1st generation (Si solar cells) and 2nd generation (GaAs as an example). In conventional semiconductors like GaAs, the CBM is predominantly determined by s orbital and the VBM is primarily determined by p orbital [32,56]. In contrast, the halide perovskites exhibit inverted electronic band structure (see Figure 3b,d)). The halide perovskites have strong optical absorption than that of the first-generation and second-generation semiconductors shown above—mainly due to the electronic band structure. The first-generation absorber (silicon) is an indirect bandgap material and its transition probability between conduction and valence band edges is about two orders of magnitude lower than that of the direct bandgap semiconductors (halide perovskite or GaAs), therefore, making its absorber layer to be two orders of magnitude thicker and consequently increasing the material cost.
Though GaAs and CH3NH3PbI3 have direct bandgap, their electronic structures are very different. Dispersive s band (delocalized s orbitals) dictates the lower part of the CB of GaAs, whereas the degenerate Pb p bands dictate the lower part of the CB of the halide perovskite (CH3NH3PbI3). The atomic p orbitals exhibit relatively less dispersion than those of s orbitals. Hence, the density of states (DOS) pertaining to the conduction band minimum (CBM) is significantly higher than that of GaAs (Figure 4a) and consequently leading to higher Joint density of states (JDOS) (Figure 4b). Moreover, the energy level transition between VB and CB for CH3NH3PbI3 is contributed from mixed (Pb s, I p) to Pb p orbitals (see Figure 3b). Here, the intra-atomic transition probability between the Pb s to Pb p is relatively high in halide perovskites when compared to that of GaAs and it is the reason behind stronger optical absorption of perovskites than GaAs as shown in Figure 4c. It is worthy mentioning that optical absorption coefficient of CH3NH3PbI3 is up to 1 order of magnitude higher than that of GaAs within the visible light range and hence relatively lower thickness is needed for absorber materials to attain maximum efficiency as shown in Figure 4d [32].
Another important unique characteristic of halide perovskites is that the grain boundaries (GB) are electrically benign. Unlike in conventional polycrystalline light absorbers, where GBs are usually detrimental to solar cell performance, the effect of GBs in halide perovskites are electrically invisible [57] and reports have even shown that it is quite favourable for better device performance [58]. The electrically benign nature of GBs in halide perovskites is primarily correlated to their electronic structures. The valence band maximum (VBM) in halide perovskites is energetically much higher than I 5p due to strong coupling between Pb 6s and I 5p, which consequently increases the level of VBM. Higher VBM implicates lower defect levels or shallow defect states, therefore charge carrier recombination propagated by the defect states are much lower in halide perovskites [32]. The extremely efficient charge transport and charge collection characteristics in perovskite solar cells are also attributed to the unique electronic structure of the halide perovskites as discussed earlier. Ambipolar carrier diffusion combined with long and balanced charge carrier diffusion lengths can be added to the merits of the unique electronic structure [32,59,60].
One of the remarkable aspects of halide perovskites is their capability to produce high-quality semiconductor films from solution processing methods. For CH3NH3PbI3 thin films, four magnitude of increase in mobility (8 to 35 cm2∙V−1·s−1) has been observed by Time-resolved terahertz spectroscopy (TRTS) which can be attributed to better solution processing or deposition techniques [61,62]. Similarly, CH3NH3PbI3 thin films fabricated from PbI2 or PbAc precursor resulted in different diffusion length (LD = 200 nm vs. 600 nm, respectively) [63]. The variation of charge carrier mobility and diffusion length as a function of crystal structure of perovskite is shown in Figure 5 [61]. The variation of electronic properties depending on the measurement methods and perovskite material composition are listed in Table 2. The electronic properties relatively decrease as the perovskite phase transitions’ into the cubic structure at room temperature.
The forthcoming sections provide a brief overview of device architectures, fabrication methods and charge selective contacts employed in PSCs.

4. Perovskite Solar Cell Device Architectures

Perovskite solar cells evolved from the mesoscopic structure (Figure 6a) in which the halide perovskite semiconductors replaced the light harvesting dye [23,70,71]. Later, the liquid electrolyte was replaced with a solid-state hole conductor. The advent attracted much interest in the PV community, which resulted in the development of other device structures as shown in Figure 6b–d. The planar device structure is developed in which the perovskite absorber is sandwiched between the electron (ETM) and hole transporting materials (HTM). The n-i-p is also called as normal device structure and p-i-n structure is also called as inverted device structure. Simply, depending on the position of the ETM and HTM, the device structure varies [70,72,73,74]. The details about the different electron and hole transporting layers are discussed in the forthcoming section.
Recently, Silvia et al. [75] demonstrated perovskite solar cells with fullerene as electron transporting layer (ETL) which exhibited PCE >10% in n-i-p planar device configuration. The authors incorporated an innovative fullerene-saturation approach/strategy (the perovskite processing solution is saturated with fullerene) to avoid the damage of the fullerene film through dissolution during the deposition of the perovskite layer. Another interesting finding was also demonstrated by the same research group, where the perovskite solar cells are fabricated without the electron transport layer with solution processed methylammonium lead triiodide perovskite–C70 fullerene (MAPbI3:C70) blend films on fluorine-doped tin oxide (FTO)-coated glass substrates [76]. The ETL-free devices thus fabricated exhibited PCE of 13.6% with significantly low carrier recombination when compared to conventional MAPbI3 perovskite layer. The ETL-free devices also exhibited high photostability in comparison to the conventional regular n-i-p architecture with TiO2 based ETL.

5. Fabrication Methods

In the “one-step” deposition or spin coating method, the perovskite precursors of appropriate stoichiometry are prepared in a common solution and are then spin coated into a thin film (Figure 7a) [77]. Power conversion efficiency of over 20% has been achieved using this single step method [28,34]. In the case of “two-step” deposition method or “sequential” deposition process, two precursor solutions are prepared. For instance, a thin film is first deposited using metal halide (e.g., PbI2) precursor using spin coating process (mostly) and then the film coated substrate is dipped into the second precursor solution (Figure 7b) [78,79]. PSCs are also fabricated using the doctor blade method (PCE ~15%) and slot die coating (~12%), which could be a versatile approach for scalability [80,81]. Dual source evaporation or vacuum deposition methods was also used to deposit perovskite thin films, which provided the advantage of producing pin-hole free layers with uniform thickness—resulting in PCE of ~15% [82]. However, this method presents challenges for scalability and also requires relatively high energy for film fabrication. Hybrid approach of using both solution processing and vapour deposition to fabricate perovskite thin films was also developed. Here, the PbI2 precursor is first spin-coated and then the methyl ammonium iodide (MAI) is evaporated on top of the as-deposited PbI2 film and a PCE of ~12% was achieved using this method [83]. Table 3 lists some of the other best perovskite solar cells (PCE > 17%) fabricated using different deposition methods.

6. Charge Selective Contacts and Interfaces

Charge selective layers play an important role in the performance of PSCs. Electron transport layer (ETL) and hole transport layer (HTL) when placed on either side of the light absorbing perovskite layer, provides unidirectional pathway for charge carriers. For instance, the ETL layer allows electrons and acts as hole blocker and HTL vice versa. Therefore, the charge selective layers influence the charge transport or charge extraction properties and thus the charge recombination rate significantly. Moreover, interface engineering using the charge selective contacts can also passivate various physical and electronic defects that could exist in the perovskite film, which includes voids, pin holes, energetic barriers, defect states etc. For instance, incorporation of PEIE on top of ITO modifies the work function of ITO from 4.6 eV to 4.0 eV, thereby reducing the electronic barrier at the ITO/TiO2 interface in an ITO/PEIE/PCBM/Y: TiO2/MAPbI3/spiro-OMeTAD/Au device [28]. Such modification has shown to improve the Jsc from 18.9 to 19.9 mA∙cm−2 and increasing the FF from 65.25% to 73.28%. Similarly, reports have shown that by incorporating an ultra-thin P3TMAHT intercalating layer in the device structure for efficient hole extraction, the average PCE was improved from 8.52% to 11.28% [82]. Dedicated reviews on interfacial engineering of perovskite solar cells can be found in the literature [72,73,74]. Some of the notable materials employed in PSC device fabrication are shown in Figure 8.

7. Challenges in Perovskite Solar Cells

As discussed earlier, perovskite solar cells have seen unprecedented development in the past few years. The advancements in terms of performance efficiency were not equally matched with the fundamental understanding of inherent electronic and physio-chemical properties, modulating the photovoltaic parameters of the devices. Hence, many challenges still remain which include hysteresis phenomenon observed during solar cell operation, improving the reproducibility of efficient devices, increasing the stability of the PSCs by making it thermal and moisture stable as well as reducing the reducing the amount of toxic (Pb-containing) material used in devices. Among these, the hysteresis and stability issue are found to be the most pressing issue as they serve as the bottleneck for commercialization. Further important challenges might arise from the scalability issues involved in the fabrication of perovskite solar cells. The details are discussed in the following sections.

7.1. Hysteresis

Hysteresis in HPSCs indicates the variations in the current–voltage response curves in which the corresponding photovoltaic parameters vary depending on the direction and rate of the scan as shown in Figure 9a,b as an example. Reversible hysteresis was reported by numerous research groups in MAPbI3-based devices of all architectures (normal and inverted) [92,93,94,95]. The scanning direction is called as backward or reverse scan when the voltage is swept from positive (open circuit) to negative (short circuit), whereas the scan in the opposite direction is termed as forward scan [96]. Therefore, hysteresis imposes a serious problem on the accurate determination of perovskite solar cell efficiencies and long term device operational stability. Furthermore, there are increasing apprehensions over some reported efficiencies as the devices are vulnerable to current-voltage (I-V) hysteresis effects. Hence, it is very much indispensable to decipher the origin or mechanisms of the I-V hysteresis in order to minimize or eradicate this anomalous behaviour completely for reliable quantification.
Although the origin of hysteretic effects is still unclear, there are numerous mechanisms that have already been proposed to explain the causes. The following mechanisms (Figure 9c) are found to govern the hysteresis phenomenon in perovskite solar cells: (i) Ferroelectric polarization [94,97,98]; (ii) Ion migration [99,100,101]; (iii) Charge trapping [102,103]; and (iv) capacitive effects [104]. Dedicated reviews on hysteresis phenomenon in perovskite solar cells can be found in the literature [95]. Since the perovskite solar cells are prone to hysteresis issues, extra care should be taken while measuring the I-V data for reporting of efficiencies. Addressing this issue, an article has been published recently comprising of step-by-step guidelines for proper characterization of perovskite solar cells [105]. The authors described the characterization techniques similar to the best practices and measurement standards followed in independent efficiency measurement labs like AIST, Fraunhofer ISE and NREL etc. The protocols include: (i) Masking the cell appropriately and measuring the device area accurately; (ii) Calibrating the illumination source; (iii) Determining the steady state Jsc and Voc and simultaneously monitoring its stability; (iv) Measuring the J-V curves at the forward and reverse direction at various scan rates; (v) Measuring steady-state photocurrent at several different voltages near maximum power point; Pmax; (vi) Calculating the Jsc by integrating the IPCE data; and (vii) performing statistical analysis across multiple measurement sample sets [105].

7.2. Stability

Another major challenge in perovskite PV technology is the degradation or lifetime of perovskite solar cells. The performance efficiency of PSCs decreases over a period of time as the degradation occurs. In order to pass the standard International Electrotechnical Commission damp heat test (85 °C, 85% relative humidity), photovoltaic modules is expected to undergo less than 10% efficiency loss in 1000 h (just over 40 days) [106,107]. Given this metric for stability requirement, the perovskite solar cells are far from satisfying this condition till date. The degradation can occur when the devices are exposed to moisture, continuous illumination, thermal-stress and oxygen [40,107,108,109,110,111,112,113]. The basic degradation mechanism in PSCs is the breakdown of perovskite material under moisture or heat stress, which results in the segregation of MAPbI3 into its constituents PbI2 and MAI [114,115,116]. It is summarized as: CH3NH3PbI3 → PbI2 + CH3NH2↑ +HI↑
The perovskite CH3NH3PbI3 thin films are found to undergo decomposition under thermal stress at a temperature between ~100 °C [117] and 140 °C [118]; the decomposition rate increases further as the temperature is increased [119]. Figure 10a shows the possible pathways of degradation of perovskite via moisture ingression and iodide ion migration. Improvement in device stability by the incorporation of phosphonic acid ammonium additive in the perovskite structure of CH3NH3PbI3 is reported to increase the moisture resistance of the material by acting as a crosslink between neighbouring grains [120] is shown in Figure 10b, where the stability is remarkably improved relative to the pristine control (MAPbI3) devices. Figure 10c shows the device structure of carbon based encapsulation in triple-layer PSCs which exhibited superior device stability [121].The carbon layer protects the device from moisture ingression and the scaffolding provides protection against thermal stress [121,122]. Typically, testing under encapsulation denotes sealing the device completely in a glass or by sealing the device using thermosetting epoxy glue [123,124]. Such kind of encapsulation protects the device or adjacent films from oxygen and moisture ingression, thereby extending the long term stability of the devices. Figure 10d shows the stability enhancement in PSCs via triple (or multiple) cation mixtures with two different compositions - Cs5M and Cs0M, where Csx represents the percentage of Caesium (5% and 0%) respectively and M stands for ‘‘mixed perovskite”. Addition of small amount of Cs to MA/FA mixtures suppresses the device degradation occurring due to phase separation and also improves the device performance significantly [30].
In order to achieve the main goal of producing cost effective modules of perovskite solar cells, manufacturers must be able to deliver devices with the long term stability. Current products on the market typically have a warranty of 20–25 years (c-silicon solar cells), which suggest that the installation will retain 80% of its initial output after this time period, corresponding to a system loss of <1%/year [132]. The perovskite solar cells demonstrated by Li et al. [122] would pass the temperature or thermal stress test but yet to overcome the moisture ingression issues or pass the damp test. Research conducted over the past couple of years indicates that the major key factors of degradation namely moisture and heat must be addressed to improve the commercial viability of perovskite solar cells and to provide a competitive edge over the currently existing alternatives.
Another important challenge in the development of perovskite solar cells is the concerns with respect to toxicity of Lead (Pb) content in the perovskite material and the environmental concerns of large scale deployment in the future. Recent studies based on life cycle analysis (LCA) and environmental impact analysis (EIA) of perovskite solar cells showed that the lead content in the perovskite materials contributes only to a small proportion on the overall environmental impact during the fabrication or manufacturing process [133,134]. The potential lead pollution from the operation of a perovskite PV manufacturing plant of 1-GW capacity is relatively lower when compared with other lead emission sources such as fossil fuels, mining industries, battery technologies and other related electronics [135]. Moreover, recent findings have shown that the perovskite solar cells can be fabricated from the recycled lead from car batteries, [136] which could open up new avenues to reduce the magnitude of lead contamination in the environment from other technologies by providing a viable opportunity to reuse them in perovskite PV industry.
Furthermore, challenges pertaining to the scaling of perovskite solar cell fabrication for large scale deployment should also be addressed in near future for successful commercialization. Thus far, most of the best reported efficiencies (>20%) in perovskite PV technology were reported for miniature devices with device area less than 1 cm2. Recently, Chen et al. reported the perovskite solar cells of 1 cm2 with a certified efficiency of 15% [137]. The authors employed heavily doped inorganic charge extraction layers in planar PSCs to achieve faster carrier extraction as well as depositing a pin-hole free perovskite light absorber layer. Future development of large area perovskite solar cells should also focus on reducing the series resistance losses and conductivity issues with respect to the contacts. In addition, fabrication of high quality perovskite film with uniform microstructure across a large area could pose a significant challenge; consequently, development of other economically viable deposition techniques becomes indispensable for successful commercialization of perovskite PV technology. Moreover, most of the best reported perovskite solar cells employ gold and silver as charge collection electrodes which could prove to be uneconomical for large scale deployment and suitable alternative has to be found to mitigate such issues.

8. Outlook and Conclusions

The review presented a brief discussion of the progress and developments in the field of perovskite solar cells. The PSC technology has undergone rapid evolution in the past 5–6 years owing to several intriguing factors, including unique optical and electronic properties of halide perovskite materials namely large carrier diffusion lengths, high charge-carrier mobility, low exciton binding energy and bandgap tunability. Further progress in terms of power conversion efficiency (PCE) is predicted via improving the crystal structure quality, grain size distribution of perovskite materials along with uniform surface-coverage and careful control of structural and electronic properties of interfaces within the device. The low exciton binding energy and ambipolar charge transport properties of perovskite films makes them the right candidate for application in tandem cells using other PV-applicable semiconductors, including organic photovoltaics (OPVs), silicon (c-Si or a-Si), copper indium gallium di-selenide (CIGS), etc. [138,139]. It is expected that such a combination of materials will enable the creation of low cost and high efficiency (>25%) solar cell devices and products [139]. In order to improve the commercial viability of the perovskite PV technology, the prominent issues such as hysteresis and degradation stability (lifetime) has to be addressed from both material and device perspective. Moreover, standard testing protocols have to be developed for testing the devices for accurate evaluation of the performance and lifetime. Overall, perovskite solar cells offer a promising solution for developing the low cost PV technology that could become the game changer of solar industry.

Acknowledgments

The authors gratefully acknowledge the financial support provided by Future Solar Technologies Pty. Ltd. for this work.

Author Contributions

N.K.E. and A.U. designed the structure of the work; N.K.E contributed to all the sections. M.A.M contributed to Section 4 and Section 5 and D.W. contributed to Section 6. N.K.E. wrote the paper.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Efficiency trends of perovskite solar cells and its associated timeline. References are provided in Table 1.
Figure 1. Efficiency trends of perovskite solar cells and its associated timeline. References are provided in Table 1.
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Figure 2. (a) Crystal structure of cubic (α phase); (b) crystal structure of the tetragonal crystal system (β) phase and orthorhombic (γ) phase of MAPbX3; and (c) the tolerance factor for different perovskite material systems, t = 1 is ideal. Image: (a) copyright [40]; (b) copyright [41]; and (c) copyright [42].
Figure 2. (a) Crystal structure of cubic (α phase); (b) crystal structure of the tetragonal crystal system (β) phase and orthorhombic (γ) phase of MAPbX3; and (c) the tolerance factor for different perovskite material systems, t = 1 is ideal. Image: (a) copyright [40]; (b) copyright [41]; and (c) copyright [42].
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Figure 3. Top: Schematic of the perovskite crystal structure with respect to the A, B and X lattice sites and their contribution to the electronic structure-copyright [54]; Bottom: (a) Contributions of MA, Pb, and I on the density of state of MAPbI3 perovskite (copyright [55]). The schematic optical absorption of: (b) halide perovskite solar cell absorber; (c) first-generation (Si); and (d) second-generation (GaAs as example) (copyright [32]).
Figure 3. Top: Schematic of the perovskite crystal structure with respect to the A, B and X lattice sites and their contribution to the electronic structure-copyright [54]; Bottom: (a) Contributions of MA, Pb, and I on the density of state of MAPbI3 perovskite (copyright [55]). The schematic optical absorption of: (b) halide perovskite solar cell absorber; (c) first-generation (Si); and (d) second-generation (GaAs as example) (copyright [32]).
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Figure 4. (a) Density of states (DOS) of CH3NH3PbI3 and GaAs. The VBMs are referred to as zero energy and CBMs are marked as dashed lines; (b) the Joint density of states (JDOS) of CH3NH3PbI3 and GaAs; (c) the optical absorptions of CH3NH3PbI3, and GaAs; and (d) calculated maximum efficiencies of halide perovskites, CIS, CZTS, and GaAs as a function of film thickness (copyright [32]).
Figure 4. (a) Density of states (DOS) of CH3NH3PbI3 and GaAs. The VBMs are referred to as zero energy and CBMs are marked as dashed lines; (b) the Joint density of states (JDOS) of CH3NH3PbI3 and GaAs; (c) the optical absorptions of CH3NH3PbI3, and GaAs; and (d) calculated maximum efficiencies of halide perovskites, CIS, CZTS, and GaAs as a function of film thickness (copyright [32]).
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Figure 5. (a) Temperature dependence of the mobility; and (b) diffusion lengths as predicted for band-like transport in different phases (orthorhombic, tetragonal and cubic) of MAPbI3 perovskite. Copyright [61].
Figure 5. (a) Temperature dependence of the mobility; and (b) diffusion lengths as predicted for band-like transport in different phases (orthorhombic, tetragonal and cubic) of MAPbI3 perovskite. Copyright [61].
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Figure 6. Schematic diagrams of perovskite solar cells in the: (a) n-i-p mesoscopic; (b) n-i-p planar; (c) p-i-n planar; and (d) p-i-n mesoscopic structures. (a,b) Normal device structure; and (c,d) inverted device structure (copyright [70]).
Figure 6. Schematic diagrams of perovskite solar cells in the: (a) n-i-p mesoscopic; (b) n-i-p planar; (c) p-i-n planar; and (d) p-i-n mesoscopic structures. (a,b) Normal device structure; and (c,d) inverted device structure (copyright [70]).
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Figure 7. Representative fabrication methods for perovskite thin films: (a) one-step spin-coating method; (b) two step or sequential deposition method; (c) dual-source vapour deposition; and (d) vapour-assisted solution process (copyright [77]).
Figure 7. Representative fabrication methods for perovskite thin films: (a) one-step spin-coating method; (b) two step or sequential deposition method; (c) dual-source vapour deposition; and (d) vapour-assisted solution process (copyright [77]).
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Figure 8. Schematic of energy level diagram of representative hybrid halide perovskites and charge-extraction interlayers. The dotted lines represent the WF of the materials (copyright [91]).
Figure 8. Schematic of energy level diagram of representative hybrid halide perovskites and charge-extraction interlayers. The dotted lines represent the WF of the materials (copyright [91]).
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Figure 9. (A) The current–voltage (I-V) response with hysteresis; and (B) negligible hysteresis of HPSCs (copyright [96]). (C) Schematic showing the various processes (or origins) occurring in the perovskite solar cells (in normal device structure as an example) that could possibly lead to hysteresis phenomenon during I-V measurements (copyright [95]).
Figure 9. (A) The current–voltage (I-V) response with hysteresis; and (B) negligible hysteresis of HPSCs (copyright [96]). (C) Schematic showing the various processes (or origins) occurring in the perovskite solar cells (in normal device structure as an example) that could possibly lead to hysteresis phenomenon during I-V measurements (copyright [95]).
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Figure 10. (a) Schematic illustration of a proposed mechanism of silver iodide (AgI) formation: (1) Moisture (H2O) in air enters through pinholes into the spiro-MeOTAD (HTL) layer. (2) Decomposition of perovskite (MAPbI3) leads to an iodine containing volatile compound (MAI and/or HI. (3) Migration of the iodine containing volatile compound from the MAPbI3 layer corroding the electrode from both the top and bottom surface of silver (Ag) layer. (4) Surface diffusion of the iodine containing volatile compound. (5) Silver iodide (AgI) formation. Copyright [125]. (b) Variation of PCE as a function of time of unsealed perovskite solar cells stored in ambient air at ~55% humidity in the dark. Copyright [120]. (c) Schematic cross section of the triple-layer perovskite-based fully printable mesoscopic solar cell. Copyright [121] (d) Aging for 250 hours of a high performance Cs5M and Cs0M devices in a nitrogen atmosphere held at room temperature under constant illumination and maximum power point tracking. Copyright [30]. Table 4 shows some of the highly stable perovskite solar cells and their lifetime reported in literature.
Figure 10. (a) Schematic illustration of a proposed mechanism of silver iodide (AgI) formation: (1) Moisture (H2O) in air enters through pinholes into the spiro-MeOTAD (HTL) layer. (2) Decomposition of perovskite (MAPbI3) leads to an iodine containing volatile compound (MAI and/or HI. (3) Migration of the iodine containing volatile compound from the MAPbI3 layer corroding the electrode from both the top and bottom surface of silver (Ag) layer. (4) Surface diffusion of the iodine containing volatile compound. (5) Silver iodide (AgI) formation. Copyright [125]. (b) Variation of PCE as a function of time of unsealed perovskite solar cells stored in ambient air at ~55% humidity in the dark. Copyright [120]. (c) Schematic cross section of the triple-layer perovskite-based fully printable mesoscopic solar cell. Copyright [121] (d) Aging for 250 hours of a high performance Cs5M and Cs0M devices in a nitrogen atmosphere held at room temperature under constant illumination and maximum power point tracking. Copyright [30]. Table 4 shows some of the highly stable perovskite solar cells and their lifetime reported in literature.
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Table 1. Development trend in perovskite solar cells with details of device structure.
Table 1. Development trend in perovskite solar cells with details of device structure.
YearDevice StructurePCE (%)Reference
2009FTO/bl-TiO2/mp-TiO2/CH3NH3PbI3/Redox Liquid electrolyte/Pt3.8[19]
2011FTO/bl-TiO2/mp-TiO2/CH3NH3PbI3/Redox Liquid electrolyte/Pt6.5[22]
2012FTO/bl-TiO2/mp-TiO2/CH3NH3PbI3/Spiro-OMeTAD/Au9[23]
March 2013FTO/bl-TiO2/mp-Al2O3/CH3NH3PbI3–xClx/Spiro-OMeTAD/Ag12.3[24]
July 2013FTO/bl-TiO2/mp-TiO2/CH3NH3PbI3/Spiro-OMeTAD/Au15[25]
2013FTO/Graphene-TiO2/mp-Al2O3/CH3NH3PbI3–xClx/Spiro-OMeTAD/Au15.6[26]
December 2013ITO/np-ZnO/CH3NH3PbI3/Spiro-OMeTAD/Ag15.7[27]
August 2014ITO-PEIE/Y-TiO2/CH3NH3PbI3–xClx/Spiro-OMeTAD/Au19.3[28]
June 2015FTO/bl-TiO2/mp-TiO2/(FAPbI3)1–x(MAPbBr3)x/PTAA/Au20.1[29]
March 2016FTO/bl-TiO2/mp-TiO2/Csx(MA0.17FA0.83)(1–x)Pb(I0.83Br0.17)3/Spiro-OMeTAD/Au21.1[30]
March 2016N/A22.1[21]
Table 2. Diffusion length (LD) and mobility (μ) measured for notable hybrid perovskites thin films.
Table 2. Diffusion length (LD) and mobility (μ) measured for notable hybrid perovskites thin films.
Compound (Perovskite Thin Films)Measurement TechniqueMobility (μ) (cm2∙V−1∙s−1)Diffusion Length, LD (μm)Charge lifetime, τ (ns)Reference
CH3NH3PbI3PLQ0.660.139.6[64]
PLQ1.40.134.5[65]
TRTS8.21.267[62]
CH3NH3PbI3-xClxPLQ1.61.07273[64]
TRTS11.62.4200[62]
CH3NH3PbBr3PLQ8.91.0651[66]
CH(NH2)2PbI3PLQ0.160.1875[67]
TRTS273.1140[68]
CH(NH2)2PbBr3TRTS141.350[68]
CH3NH3SnI3TRTS1.60.030.2[69]
Legend: PLQ, Photo Luminescence Quenching; TRTS, Time-Resolved Terahertz Spectroscopy.
Table 3. Fabrication methods and performance of PSCs (for devices with PCE >17%).
Table 3. Fabrication methods and performance of PSCs (for devices with PCE >17%).
Fabrication MethodDevice ConfigurationJsc (mA/cm2)Voc (V)FF (%)PCE (%)Reference
Single stepFTO/bl-TiO2/mp-TiO2/CH3NH3PbI3/Spiro-OMeTAD/Au22.41.0979.619.1[84]
Single stepFTO/bl-TiO2/mp-TiO2/(FAPbI3)1–x(MAPbBr3)x/PTAA/Au24.71.0677.520.2[29]
Single stepITO-PEIE/Y-TiO2/CH3NH3PbI3–xClx/Spiro-OMeTAD/Au22.71.1375.019.3[28]
Two stepITO/NiOx/perovskite/ZnO/Al21.01.0176.016.1[85]
Two stepFTO/bl-TiO2/mp-TiO2/cuboid-CH3NH3PbI3/Spiro-OMeTAD/Au21.61.0574.117.0[27]
Single stepFTO/bl-Al2O3/mp-TiO2/CH3NH3PbI3/Spiro-OMeTAD/Ag23.81.0876.219.7[86]
Two stepFTO/bl-TiO2/mp-TiO2/CH3NH3PbI3/Spiro-OMeTAD/Au21.41.067617.1[87]
Single stepFTO/PEDOT:PSS/CH3NH3PbI3–xClx/PCBM/Al22.40.928218.0[88]
Single stepFTO/TiO2/(FAPbI3)1–x(MAPbBr3)x/PTAA/Au21.81.1173.617.9[34]
Single stepITO/PEDOT:PSS/CH3NH3PbI3/PCBM/Au20.91.107918.1[89]
Single stepFTO/SnO2/(FAPbI3)0.85(MAPbBr3)0.15/Spiro-OMeTAD/Au21.31.147418.4[90]
Table 4. List of some of the stable perovskite solar cells and lifetime values in literature.
Table 4. List of some of the stable perovskite solar cells and lifetime values in literature.
Device StructureEfficiency (%)Expt. Conditions (Light, Moisture, Temperature)StabilityReference
FTO/TiO2/Al2O3 + MAPbI3−xClx/Li-spiro/Ag12.680°C, air48 h[126]
FTO/c-TiO2/MAPbI3−xClx/spiro/Au9.2Dark, air3 months[127]
FTO/TiO2/Al2O3/MAPbI3−xClx/spiro/Au10.2Ambient, 100 mW cm−2 light Encapsulated device60% decrease in PCE after 175 h[128]
FTO/c-TiO2/m-TiO2 and ZrO2/(5-AVA)x(MA)1−xPbI3/carbon film12.8Room temperature, 1.5 simulated sunlight1008 h[121]
FTO/c-TiO2/MAPbI3−xClx/spiro/Au10.2Room temperature, air, humidity < 35%15 days, PCE dropped by one order of magnitude[129]
FTO/c-TiO2/MAPbI3−xClx/spiro/Au16.03Bare device, no encapsulation, stored under ambient condition62 days: 9% decrease in PCE[130]
FTO/TiO2 nano-rod + TiCl4/MAPbI3−xClx/spiro/Au10.6Room temperature, air, humidity < 35%55 days, 60% of initial PCE is retained[129]
ITO/NiOx/perovskite/ZnO/Al14.6Air, room temperature, no encapsulation60 days, 90% of initial PCE is retained[85]
FTO/c-TiO2/m-TiO2/FEAI-MAPbI3/spiro/Au18Air, room temperature, no encapsulation120 days, 92% of initial PCE is retained[131]

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Elumalai, N.K.; Mahmud, M.A.; Wang, D.; Uddin, A. Perovskite Solar Cells: Progress and Advancements. Energies 2016, 9, 861. https://0-doi-org.brum.beds.ac.uk/10.3390/en9110861

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Elumalai NK, Mahmud MA, Wang D, Uddin A. Perovskite Solar Cells: Progress and Advancements. Energies. 2016; 9(11):861. https://0-doi-org.brum.beds.ac.uk/10.3390/en9110861

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Elumalai, Naveen Kumar, Md Arafat Mahmud, Dian Wang, and Ashraf Uddin. 2016. "Perovskite Solar Cells: Progress and Advancements" Energies 9, no. 11: 861. https://0-doi-org.brum.beds.ac.uk/10.3390/en9110861

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