Abstract
SCAPS simulation was utilized to complement previously published perovskite-on-Si tandem solar devices and explore herein viable all-perovskite 4-T mechanically stacked and 2-T monolithic non-Pb tandem structures. CsSn0.5Ge0.5I3 (1.5 eV) was used as top cell wide bandgap absorber, while CsSnI3 (1.3 eV) was chosen as bottom cell low bandgap absorber. The top cell was simulated with AM 1.5G 1 Sun spectrum, and the bottom cell was simulated with the filtered spectrum from the top cell. To form a 2-T monolithic tandem device, ITO was used as the recombination layer; the current matching condition was investigated by varying the thickness of the absorber layers. For a current-matched device with a Jsc of 21.2 mA/cm2, optimized thicknesses of 450 nm and 815 nm were obtained for the top and bottom absorber layers, respectively. At these thicknesses, the PCEs of the top and bottom cells were 14.08% and 9.25%, respectively, and 18.32% for the final tandem configuration. A much simpler fabricated and simulated 4-T mechanically stacked tandem device, on the other hand, showcased top and bottom cell PCEs of 15.83% and 9.15%, at absorber layer thicknesses of 1300 nm and 900 nm, respectively, and a final overall tandem device PCE of 19.86%.
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1 Introduction
The global energy demand is expected to double from 15 TW (2011) to 30 TW (2050) [1,2,3]. Eighty-one percent of our energy demand is supplied by fossil fuel. Renewable energy, by and large, has yet to catch up to the mainstream energy market. Tandem devices of various configurations continue to be thoroughly investigated to overcome the Shockley–Queisser theoretical power conversion efficiency (PCE) limit of 31% for the prevalent single-junction Si technology. In the last decade, III–V compound semiconductors in conjunction with Ge have been employed to achieve device PCE values of up to 39% under 1 Sun [4, 5]. Among other high-performing devices, multi-junction solar cell structures such as GaInP/GaAs/GaInAsP/GaInAs have demonstrated PCE values as high as 44.7% [6]. Unfortunately, these technologies require costly materials and intricate manufacturing processes, making them difficult to scale up within a commercial setting [7].
The halide perovskite technology in the past decade has provided researchers with a viable alternative to the afore-mentioned materials. Perovskite materials boast a suite of critical properties including tunable bandgaps, excellent absorption coefficients, long carrier recombination lifetimes, high electron, and hole mobilities, small electron/hole effective masses, low exciton binding energies, low cost, and solution-based fabrication process [8,9,10]. Perovskite-on-Si tandem solar devices have been successfully investigated to enhance PCE while bringing down the levelized cost of efficiency (LCOE) of the technology [7]. Additionally, all-perovskite tandem devices offer a route to high efficiency while maintaining the benefits of low-cost and low-temperature fabrication, together with the advantages of being lightweight and having flexible form factors [7]. These advantages are promising when juxtaposed against the constraints of the prevalent Si technology which include a need for materials quality improvement for PCE enhancement together with driving down costs [11].
Single-junction solar device physics shows that photons with energy lower than the bandgap of the absorber will not be absorbed; on the flipside, photons with higher energy will undergo thermalization losses. Multi-junction solar cells can optimize on device functionality by using several semiconductor absorbers with different bandgaps. In tandem devices, a “top cell” with a large bandgap absorber material absorbs high-energy photons, permitting lower-energy photons to pass through to be absorbed in the ‘bottom cell’ containing a small bandgap absorber. Thus, the higher-energy photons generate a high voltage in the top cell, while the low-energy photons generate a lower voltage in the bottom cell, raising the obtainable efficiency of the combined tandem cell over that of either cell.
Tandem solar devices are traditionally assembled either through a mechanical stacking or a monolithic arrangement. Two-terminal (2-T) monolithic tandem devices require low-temperature processing for the top cell to be directly processed on top of the bottom cell and connected by a recombination layer. Due to the 2-T configuration, only a single transparent conductive electrode is needed, lowering parasitic absorption and thus manufacturing cost. Efficient recombination contacts include highly doped n- and p-type layers, intermediate transparent conductive oxides [TCO, such as indium-doped tin oxide (ITO)] or (ultra) thin metal layers [12]. Overall, it is challenging to fabricate high-efficiency monolithic devices due to the complexity of processing. In a mechanical stacking configuration, on the other hand, the high bandgap cell is mechanically mounted on top of the low bandgap cell. The sub-cells are fabricated independently, often by incompatible processes; mechanically stacked tandem devices are typically of a four-terminal (4-T) architecture. In the laboratory and manufacturing space, mechanical stacking is often the preferred method of tandem device fabrication due to the simplicity of implementation; it is also the simpler and more accurate method to simulate through software such as SCAPS.
Lead (Pb) halide perovskites as photo-absorbers have showcased rapid PCE improvement in the past decade from 3.8 to 25.2% [13,14,15]. These Pb-based perovskite materials possess several appealing properties such as wide absorption range, large diffusion length, and high-charge-carrier mobility. While recent studies on plants suggest that the perovskite toxicity at low concentrations is solely caused by iodide ions [16], the toxicity of lead associated with the lifecycle of PSCs cannot be ignored either and poses a significant hurdle in the path toward the technology’s commercialization [17,18,19]. Interesting future work can focus on the relative impacts of replacing iodine and lead by their non-toxic counterparts, and quantifying impacts on device performance including efficiency, stability, and degradability.
Our current work aims to introduce a tandem solar configuration that is stable, non-toxic, and cost-effective, in an effort toward responsible commercial viability. Recently, CsSn0.5Ge0.5I3 has been reported to have shown high stability under ambient conditions without encapsulation. The formation of an ultrathin (< 5 nm) uniform native-oxide surface passivating layer on the CsSn0.5Ge0.5I3 perovskite has been critical in providing it with superior stability, even compared with the prototypical MAPbI3 perovskite. It has been additionally shown that CsSn0.5Ge0.5I3 perovskite thin films can be fabricated through a facile one-step method, yielding devices with PCE up to 7.11% [20]. Lastly, CsSn0.5Ge0.5I3 solar devices have been shown to be highly stable upon continuous operation under 1-sun illumination for over 500 h [20]. The inorganic perovskite CsSnX3 (X = I, Br, Cl), additionally, has been considered to be a viable material to construct various optoelectronic devices, such as photodetectors, memories, solar cells, and light-emitting diodes [21]. CsSnI3 showcases the smallest bandgap in CsSnX3 perovskites family [22], together with a high thermal stability, making it an attractive material for a solar device [22]. By utilizing melt-synthesized cesium tin iodide (CsSnI3) ingots that contains high-quality large single-crystal (SC) grains, CsSnI3 devices have shown marked improvement in bulk carrier lifetimes, doping concentration, and minority-carrier diffusion lengths [23]. Additionally, these devices exhibit low surface recombination velocity (of 2 × 103 cms−1) [23], similar to Pb-based perovskites. The electric structure, ferroelectricity, and structural phase transitions of lead-free CsSnI3 perovskite films have been studied using first-principle-based calculations as well [24, 25]. In the study of the effect of additives on device stability, it has been summarized that additives can passivate the surface and improve the stability of CsSnI3 films, e.g., addition of SnBr2 additive in CsSnI3 films has resulted in longer stability [26]. The most consequential impediments for the exploitation of CsSnI3 in optoelectronic devices include the presence of a non-optically active polymorph [27] competing with the optically active polymorph at room temperature, together with the tendency of Sn to oxidize. To overcome these limitations, pulsed laser deposition (PLD) has been utilized as a unique single-source in-vacuum deposition technique for the perovskite’s fabrication [27].
In previous work, the authors have explored a 2-T monolithic tandem devices utilizing perovskite-on-Si structures [28]. In this current work, we have explored a 4-T mechanically stacked and a 2-T monolithic all-perovskite tandem solar device utilizing CsSn0.5Ge0.5I3 and CsSnI3 as non-toxic absorber layers using SCAPS solar cell simulation software. For the 2-T monolithic tandem device, the strict criteria of current matching between the two sub-cells made of the two unique absorbers are explored by varying the thicknesses of individual layers. The dependency of device performance on absorber layer thickness is also explored for the 4-T mechanically stacked tandem. Optimal performance outputs for the top and bottom cells for both configurations are showcased and compared against the final tandem PCE values for each.
2 Methodology
In this study, the numerical simulation of perovskite–perovskite tandem solar cell is conducted using SCAPS (solar cell capacitance simulator) software, developed by the Department of Electronics and Information Systems (ELIS) of the University of Gent, Belgium [29,30,31]. SCAPS solves three main governing equations—transport, Poisson, and continuity equations—for the generated carriers. The Poisson equation is given by:
where V(x) is the electrostatic potential, q is the charge on the electron, \(\varepsilon\) is the permittivity of the absorber, \(N_{A}^{ - }\) and \(N_{D}^{ + }\) are acceptor and dopant densities, respectively, and p(x) and n(x) are position-dependent electron and hole concentrations, respectively. The carrier continuity equations are given by:
where \(J_{n} , J_{p}\) are electron and hole current density and R(x) and G(x) represent recombination and generation rates, respectively. The drift–diffusion equations for electrons and holes are given by:
where \(\mu_{n} , \mu_{p}\) are mobility of electrons and holes and \(Dn, Dp\) are the diffusion constant for electrons and holes, respectively.
SCAPS-1D does not support simulation of a multi-junction solar cell fully. In the mechanism of the tandem solar device, the top cell contains the higher bandgap perovskite, and the lower bandgap material is in the bottom cell. We first simulated the top cell with the standard AM 1.5G 1 Sun spectrum which was followed by the filtration of the incident AM 1.5G spectrum using the model mentioned below. The bottom cell was then simulated using the filtered spectrum from the top cell. For the 2-T monolithic tandem, a recombination layer (ITO) was introduced and the condition where the current densities of the two cells match are matched was fulfilled by varying the thicknesses of the two perovskite materials. This method is widely used in the simulation of tandem cells using SCAPS-1D [11, 32, 33].
The device fill factor (FF) is defined as follows:
here Jmp and Vmp are the current density and voltage at the maximum power point, respectively.
Device efficiency, \({ }\eta\), normalized to input power, Pin, is defined as:
Additional relevant equations are listed as follows:
where \(N_{{{\text{phot}}}} \left( {\lambda ,x} \right)\) is the photon flux at position x, \(N_{{{\text{phot}}0}} \left( \lambda \right)\) is the photon flux at position x = 0, \(T_{{{\text{front}}}} \left( \lambda \right)\) is the transmission of the front contact, \(a\left( \lambda \right)\) is the absorption coefficient, d represents the thickness of a layer, \(R_{{{\text{back}}}} \left( \lambda \right)\) is the reflection at the back contact, \(R_{{\text{int}}}\) is the internal reflection at the front contact, \(S_{0} \left( \lambda \right)\) is the incident A.M 1.5G spectrum, \(S\left( \lambda \right)\) is the filtered spectrum from the top cell, and \({\text{mat}}_{i}\) represents a particular material (i = 1 for Spiro-OMeTAD, 2 for CsSn0.5Ge0.5I3, 3 for PCBM and 4 for SnO2).
Figure 1 shows a plot of the filtered AM1.5G spectrum used to simulate the bottom cell in the tandem for top cell thickness.
3 Device structure and simulation parameters
3.1 Device architecture
For a tandem solar device to function optimally, it becomes important to carefully choose the absorbers (with particular bandgaps) for the top and the bottom cells. Optimal top-band gap energies would ideally be higher (up to around 1.8 eV). But for such high bandgaps halide segregation issues are problematic [34, 35]. Leijtens et al. [7] have shown perovskites with bandgap in the range 1.55–1.63 eV to have the most promising characteristics for top cells in tandem devices because of their high spectral efficiency and stability under operation conditions [36, 37]. To provide some perspective, previously published tandem (perovskite-on-perovskite) device efficiencies are listed in Table 1.
For our device, Fig. 2a, b represents the schematics of the top and bottom cells for two different configurations—2-T monolithic and 4-T mechanically stacked—of the tandem device. Figure 2a shows the sub-cells of the 2-T monolithic tandem cell connected in series utilizing ITO as the recombination layer. The 4-T mechanically stacked tandem device, as shown in Fig. 2b, comprises two independent sub-cells connected externally. Upon solar irradiation, electron/hole pairs are created in the perovskite layers; while electrons jump from the perovskite layer to the ETL, holes hop from the perovskite layer to the HTL.
The top cell of both configurations consists of Spiro-OMeTAD as the HTL, PCBM as the ETL, and CsSn0.5Ge0.5I3 as the wide bandgap (1.5 eV) perovskite. The experimental feasibility of this device has been demonstrated by Chen et al. [41]. The bottom cell consists of PTAA as the HTL, TiO2 as the ETL, Au as the metal back contact, and CsSnI3 (1.3 eV) as the low bandgap perovskite material. For the perovskite-on-perovskite tandem device, the top cell is simulated with the standard A.M 1.5G 1 Sun spectrum and the bottom cell is simulated by the filtered spectrum obtained after passing through the top cell. This filtered spectrum that strikes the bottom cell is shown in Fig. 1 (plotted as function of top cell absorber layer thickness).
Figure 3 highlights important band alignment between adjacent layers in each cell. Each material layers’ conduction and valence bands are stacked up with respect to each other—the comparative positions are critical in ensuring charge transport across the device. As previously mentioned, upon solar irradiation, electron/hole pairs are created in the perovskite layer; while electrons jump from the perovskite layer to the ETL, holes hop from the perovskite layer to the HTL. A higher electron affinity (EA) of the ETL compared to the perovskite layer ensures the successful conduction of electrons at the ETL/perovskite interface, while a similar dynamic for hole conduction at the perovskite/HTL interface necessitates a higher EA of the perovskite compared to that of the HTL (listed in Table 2). With the conduction band of the HTL positioned above of that of the perovskite additionally ensures the prevention of the back flow of electrons. There is therefore an intimate dependency of the device Jsc and the Voc upon energy level disparities at both interfaces.
3.2 Simulation parameters
Input parameters have been carefully chosen from published literature [31, 42, 43] and experimental works [20, 22, 44,45,46,47,48]. These parameters are listed in Table 2.
4 Results and discussion
4.1 Validation studies: SCAPS results compared against published literature
Table 3 provides a breakdown of the comparison between our simulated results for the top and bottom cells against experimentally published results [41, 44]. For the bottom cell, thickness values for PTAA, TiO2, and CsSnI3 are 150, 140, and 700 nm, respectively. For the top cell, optimal thickness for Spiro-OMeTAD, PCBM, SnO2, and CsSn0.5Ge0.5I3 is 150, 140, 50, and 200 nm, respectively. As can be seen, there is good congruence between the two sets of results.
4.2 J–V and EQE of top and bottom cells with optimized layer thicknesses
Simulated J–V graph for standalone top and bottom cells with optimized layer thicknesses is shown in Fig. 4a. Each cell has been simulated separately under AM 1.5G 1 Sun spectrum. The top cell shows a higher Voc compared to the bottom cell as a result of the higher bandgap of CsSn0.5Ge0.5I3; Jsc, on the other hand, is lower for the top cell compared to the bottom cell. This result is proof of the intricate dynamics and dependencies of the critical layer parameters, together with interfacial parameters, as shown in Table 2. External quantum efficiency (EQE) performances of the two cells are also shown in Fig. 4b. The better performance of the top cell in the energy range shown is consistent with its higher Jsc value as enumerated above.
4.3 2-T monolithic tandem device: impact of absorber layer thickness in top and bottom cells
For the monolithic 2-T tandem device, both the top and the bottom cells should have the same Jsc [11]. As already mentioned, from Fig. 4, we can see the two cells have different Jsc values. To ultimately obtain the current matching condition, investigation into the impact of thicknesses variation on the top and the bottom performance has first been carried out.
The impact of absorber layer thickness on device performance is shown in Fig. 5. From the figure, we can see that for both cells, Jsc increases with increasing absorber layer thickness [49]. These improvements are due to the natural increase in the absorption of the photons due to more absorber material, leading to the generation of more electron–hole pairs and their consequent movement to the electrodes. However, current density saturates at higher absorber layer thickness values, and so the increase is more significant in the lower layer thickness range. The Jsc values of the top cell for the thicknesses 400, 600, 800, 1000, and 1200 nm are 20.6, 22.7, 23.9, 24.7, and 25.2 mA/cm2, respectively (Fig. 4a). Improvement of Jsc with the increase in the perovskite layer thickness is also true for the bottom cell (Fig. 5b). J–V curves for the CsSnI3 perovskite thickness of 400, 600, 800, 1000, and 1200 nm are 29.8, 35.6, 38.7, 40.4, and 41.0 mA/cm2, respectively. Lastly, it is also seen that the Voc of the top cell is less sensitive to the thickness of the absorber compared to the bottom cell.
To provide validity for the tandem structure functionality in the way that optical coupling occurs across the top and bottom cells, J–V curves of the bottom cell under spectrum filtered from the top cell (with different thicknesses) are shown in Fig. 5c. Here, the thickness of the bottom cell is kept constant at 800 nm, while the thicknesses of the top cell have been changed. As expected, the higher the top cell thickness, the more it absorbs incoming photons, leading to lower photocurrent in the bottom cell. These trends are shown in Fig. 5c.
4.4 Simulation of perovskite-on-perovskite 2-T monolithic tandem solar device
The methodology of tandem device simulation is described in Sect. 3.1. The top cell was simulated with the incident AM 1.5G 1 Sun spectrum \(S_{0} \left( \lambda \right)\), and the transmitted spectrum, after the absorption by the top cell, was calculated with the help of Eq. (11).
Electrically, a 2-T tandem solar device can be considered as two diodes connected in series—this is the crucial reason why the same current must pass through both cells [11]. The cell with the minimal Jsc value limits the Jsc of the entire tandem device. Taking all the above into consideration during our simulation, the thicknesses of the two absorber layers were optimized to ensure that both have the same Jsc in the tandem device [50,51,52,53]. To this end, the top cell was simulated by varying the absorber (CsSn0.5Ge0.5I3) layer thickness from 200 to 1500 nm, while the thicknesses of the remaining layers were kept constant. For each given top absorber layer thickness, the unique filtered transmitted spectrum was used to irradiate the bottom cell. The optimal current matching setting showcases a value of 21.22 mA/cm2 with 450 nm as top cell CsSn0.5Ge0.5I3 thickness and 815 nm as bottom cell CsSnI3 thickness. The PV parameter outputs utilizing the optimized layer thickness values are listed in Table 4. Figure 6 shows the J–V curves of the top and bottom cells and the final tandem device. For the tandem device, each current matched (J) value from the top and bottom cells gave unique voltage (V) values for the corresponding cell. These V values were added together to give the voltage for the tandem device. A unique plot of J versus V for the tandem device could thus be plotted.
It is encouraging to see a performance output of 18.32% from the tandem device, which is higher than either of its components which showcase values of 14.08% and 9.25% (top and bottom cells, respectively). This final PCE, while less than what Pb-based tandem devices typically showcase—e.g., MAPbI3 perovskite on top of crystalline silicon, a two-terminal monolithic perovskite/crystalline silicon tandem device outputs a PCE of 21.2% [54] and a 4-T all-perovskite tandem cell with MAPbI3 in the top cell outputs a PCE of 23% [55]—is competitive enough to garner interest in our device as a feasible non-toxic alternative for production at a manufacturing level.
4.5 Simulation of perovskite-on-perovskite 4-T mechanically stacked tandem solar device
As mentioned in “Introduction,” the processing of a 4-T mechanically stacked tandem device is easier compared to a 2-T monolithic tandem device because of its configuration where the two sub-cells can be fabricated separately and be contacted independently. Additionally, as shown in Sect. 4.3, the short-circuit current density, Jsc, of the 2 T devices is limited by the lowest Jsc containing sub-cell [56] and to match the current density in both the sub-cells the processing requires close control.
As has been showcased multiple times in previous sections, device PCE is a function of absorber layer thickness. In this case, for our 4-T mechanically stacked tandem, the effect of absorber layer thickness on PCE is shown in Fig. 7. Increasing absorber layer thickness results in an increase in device PCE due to higher numbers of generated electron–hole pairs, leading to higher photo-current. Jsc reaches a maximum and falls thereafter as the effects of recombination losses due to an increasing number of defect centers (also a function of absorber thickness) become stronger [28, 31].
For the standalone CsSn0.5Ge0.5I3 perovskite top cell under AM 1.5G 1 Sun spectrum, a maximum PCE of 15.83% is obtained at an absorber layer thickness of 1300 nm. For the standalone CsSnI3 bottom cell, a maximum PCE of 9.5% is obtained at an absorber layer thickness of 900 nm. According to these observations, the above-mentioned thicknesses have been selected for the 4-T mechanically stacked tandem configuration. PV output parameters for this device are highlighted in Table 5. In addition, Fig. 8 illustrates the J–V curves of the top and bottom cells. A larger photo-current is produced in the top cell compared to the bottom cell because the bottom cell was illuminated with the filtered AM 1.5 G spectrum.
It is interesting to note that the 4-T mechanically stacked tandem device showcases a higher PCE of 19.86%, compared to 18.32% in that the 2-T monolithic tandem device outputs (Table 4). We attribute this difference to losses that occur at the recombination ITO layer in the 2-T monolithic tandem configuration. Our results provide a further motivation—beyond simplicity of implementation—for researchers to probe higher performing 4-T mechanically stacked all-perovskite tandem devices and compare against their 2-T monolithic counterparts.
5 Conclusion
Lead-free perovskite materials, CsSn0.5Ge0.5I3 (bandgap 1.5 eV, top cell), and CsSnI3 (bandgap 1.3 eV, bottom cell), have been utilized to form both 4-T mechanically stacked and 2-T monolithic perovskite-on-perovskite tandem solar devices to enhance device PCE compared to standalone devices. This research complements previously published work wherein perovskite-on-Si tandem structures were investigated. The top cell was simulated with AM 1.5G 1 Sun spectrum, and the bottom cell was simulated with the filtered spectrum from the top cell. To form a 2-T tandem device, ITO was used as the recombination layer; the current matching condition was investigated by varying the thickness of the perovskite layers. For a current-matched device with a Jsc of 21.2 mA/cm2, optimized thicknesses of 450 nm and 815 nm were obtained for the top and bottom perovskite layers, respectively. At these thicknesses, the PCEs of the top and bottom cells were 14.08% and 9.25%, respectively, and 18.32% for the final tandem configuration. By contrast, a much simpler 4-T mechanically stacked tandem device showcased bottom and top cell PCEs of 9.15% and 15.83%, with an overall tandem device PCE of 19.86%. For both the configurations, it is encouraging to see a noticeable performance improvement that the tandem device showcases over each individual sub-cell. It is equally important to note that beyond the advantage of simplicity (either through fabrication or simulation) that a 4-T mechanically stacked tandem device offers over its 2-T monolithic counterpart, it also showcases a higher PCE. Overall, our findings for both of the fully non-Pb tandem solar devices show that the final PCE values, although less than what Pb-based devices typically produce, are competitive enough to garner interest in such devices as a feasible non-toxic alternative for production at a manufacturing level.
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SA acknowledges the support of the Clean Energy Grant (Project #53) from SUNY Buffalo State.
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Islam, M.T., Jani, M.R., Rahman, S. et al. Investigation of non-Pb all-perovskite 4-T mechanically stacked and 2-T monolithic tandem solar devices utilizing SCAPS simulation. SN Appl. Sci. 3, 504 (2021). https://doi.org/10.1007/s42452-021-04487-7
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DOI: https://doi.org/10.1007/s42452-021-04487-7