“Unleaded” Perovskites: Status Quo and Future Prospects of Tin‐Based Perovskite Solar Cells

Ke, Weijun; Stoumpos, Constantinos C.; Kanatzidis, Mercouri G.

doi:10.1002/adma.201803230

Cited by 398 publications

(406 citation statements)

References 217 publications

(495 reference statements)

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“…The hysteresis index (HI) can be calculated according to the equation of

HI = [J_{RS} (0.8 V_{OC}) - J_{FS} (0.8 V_{OC})] / J_{RS} (0.8 V_{OC})

, where J RS (0.8 V OC ) and J FS (0.8 V OC ) represent the photocurrent density at 80% of V OC for the RS and FS, respectively . With the aid of TP, the HI is decreased from 12.85% to 0.84%, and the V OC is increased from 0.48 to 0.62 V, indicating that the corresponding PSCs have higher‐quality perovskite films and less trap states . Figure c shows the corresponding external quantum efficiency (EQE) of control device and the other device with TP addition.…”

Section: Resultsmentioning

confidence: 99%

“…[51] With the aid of TP, the HI is decreased from 12.85% to 0.84%, and the V OC is increased from 0.48 to 0.62 V, indicating that the corresponding PSCs have higher-quality perovskite films and less trap states. [52] Figure 4c shows the corresponding external quantum efficiency (EQE) of control device and the other device with TP addition. The two devices both exhibited wide optical response in a wide spectral range from the near-infrared region to ultraviolet wavelength region.…”

Section: Resultsmentioning

confidence: 99%

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Stabilization of Inorganic CsPb_0.5Sn_0.5I₂Br Perovskite Compounds by Antioxidant Tea Polyphenol

et al. 2019

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Implementation of inorganic perovskite compounds and reduction toxicity of lead are important for developing sustainable and renewable photovoltaic power generation. The inorganic Pb/Sn binary metal halide perovskites offer a perfect opportunity for tuning optical bandgap and thus hold significant potential in emerging technologies such as solar cells. However, an easy oxidation of Sn2+ to Sn4+ has become one of the main issues for achieving efficient and stable Sn‐based perovskite solar cells (PSCs). Herein, an effective method for stabilizing CsPb0.5Sn0.5I2Br is proposed to realize high‐efficiency PSCs via antioxidant tea polyphenol (TP). It is found that TP can not only slow down the oxidation of Sn2+ but also regulate perovskite film crystallization during the formation of perovskite films via coordination interaction, leading to a reduced density of defects and an enlarged open‐circuit voltage. The resultant perovskite solar cell using CsPb0.5Sn0.5I2Br (TP) with an all‐inorganic mesoscopic framework of FTO/c‐TiO2/m‐TiO2/Al2O3/NiO/carbon achieves an impressive power conversion efficiency of 8.10% with high stability.

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“…The hysteresis index (HI) can be calculated according to the equation of

HI = [J_{RS} (0.8 V_{OC}) - J_{FS} (0.8 V_{OC})] / J_{RS} (0.8 V_{OC})

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Stabilization of Inorganic CsPb_0.5Sn_0.5I₂Br Perovskite Compounds by Antioxidant Tea Polyphenol

et al. 2019

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“…Long‐term exposure to Pb causes severe nerve and brain damage . This toxicity issue boosts the development of Pb‐less or Pb‐free perovskites. From computational studies, the conduction band of perovskite is predominantly derived from the unoccupied p orbitals of Pb while the valence band is constituted mainly by halogen p orbitals mixed with a small amount of s orbitals of Pb .…”

Section: Alkaline‐earth Cationsmentioning

confidence: 99%

“…The isoelectronic s 2 p 2 group IV elements such as Sn and Ge are thus the most apparent candidates to replace Pb. However, the efficiency of PVSCs incorporating Sn and/or Ge is still lagging behind that of Pb‐based analogs since only the heavy Pb 2+ with an s 2 electron pair in group IV is stable due to the relativistic contraction, while the upper group elements Sn and Ge are more stable in the +4 oxidation state, which leads to lattice vacancies and critical stability issues for the perovskite layers . Therefore, it is crucial to search for alternative candidates for low toxic development as well as enhancing performance.…”

Section: Alkaline‐earth Cationsmentioning

confidence: 99%

Metal Cations in Efficient Perovskite Solar Cells: Progress and Perspective

et al. 2019

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dramatically stimulate the development of perovskite solar cells (PVSCs). Benefiting from the constant optimization of functional materials and preparation methods, the power conversion efficiency (PCE) of PVSCs has skyrocketed from 3.8% [15] to a certified value of 24.2% [16] in several years, on a par with the commercialized photovoltaics such as thin-film CdTe and silicon solar cells. [17] In general, the 3D metal halide perovskites possess an ABX 3 structure, where A is a monovalent cation, B is a divalent metal cation, and X is a monovalent halide anion. The ionic radius have to meet the requirement of Goldschmidt's empirical tolerance factor ( (where r is the ionic radius, 0.8 < t < 1) to maintain the 3D perovskite framework. [18,19] For photovoltaic applications, the A-site typically utilizes methylammonium (MA + ), formamidine (FA + ) or Cs + , B can be Pb 2+ or Sn 2+ and X is Br − or I − . Among them, each cxombination can individually form a photoactive perovskite phase and most of the milestone PCEs were attained by mixing the composition of MA/FA/Cs cations and I/Br anions. [20][21][22][23][24][25][26] Beyond all doubt, the properties of perovskite, such as morphology, crystallinity, and trap-state density, have a major influence on the photovoltaic performance of PVSCs. For instance, the photovoltage mainly stems from the splitting of the quasi-Fermi levels in perovskite under illumination. [27,28] Moreover, trap states generated by undercoordinated atoms can trigger nonradiative recombination, ion migration and stability issues. [29] Therefore, various strategies focusing on preparation methods, [30,31] additive engineering [32] and interface modification [33][34][35] have been developed to optimize perovskite quality. Among them, optimizations on fabrication approaches are the dominant driving force to boost the PCE of PVSCs and have been extensively investigated from initial one step deposition, [36][37][38] through two steps, [39,40] vacuum deposition [41,42] and finally to antisolvent engineering. [43][44][45] But beyond that, additive engineering with the advantage of directly tailoring the properties of perovskite is regarded as a paramount and effective approach. Quintessentially, the additives are broken down into two categories: 1) organic additives including small molecules, fullerenes and polymers; 2) inorganic additives including metal cations, inorganic acids and nanoparticles. Almost all of them can govern the crystallization of perovskite and enhance stability. [32] However, organic additives generally passivate only Metal halide perovskite solar cells (PVSCs) have revolutionized photovoltaics since the first prototype in 2009, and up to now the highest efficiency has soared to 24.2%, which is on par with commercial thin film cells and not far from monocrystalline silicon solar cells. Optimizing device performance and improving stability have always been the research highlight of PVSCs. Metal cations are introduced into perovskites to further optimize the quality, and this strategy is...

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“…A massive effort was headed toward the simultaneous substitution of Pb, A-site cation and/or anion; however, combinations including a single B-site replacement capable to preserve the abovementioned virtues of lead perovskites remained elusive so far (promising exceptions are Sn-based perovskites [27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42][43][44] for solar cells and Ge-based layered perovskites [45][46][47][48][49][50] for LEDs).…”

Section: Introductionmentioning

confidence: 99%

Ag/In lead‐free double perovskites

Liu

Marongiu

Pau

et al. 2020

EcoMat

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Lead‐free Cs2AgInCl6 and Cs2AgInBr6 double perovskites are studied by a combination of advanced ab‐initio calculations and photoluminescence experiments. We show that they are insulators with direct band gaps of 2.53 and 1.17 eV, respectively; most importantly, they are characterized by unusually low absorption rates in a ~1 eV wide energy region above the band gap, caused by rather peculiar electronic properties. Consequently, this low absorption conveys very long recombination lifetimes, up to milliseconds at low temperature. Our theoretical analysis suggests that such materials can achieve a good compromise between photoconversion efficiency (above 10%) and visible transmittance (above 30%), which makes them potentially suited for lead‐free semitransparent solar cell applications.

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“Unleaded” Perovskites: Status Quo and Future Prospects of Tin‐Based Perovskite Solar Cells

Cited by 398 publications

References 217 publications

Stabilization of Inorganic CsPb_0.5Sn_0.5I₂Br Perovskite Compounds by Antioxidant Tea Polyphenol

Stabilization of Inorganic CsPb_0.5Sn_0.5I₂Br Perovskite Compounds by Antioxidant Tea Polyphenol

Metal Cations in Efficient Perovskite Solar Cells: Progress and Perspective

Ag/In lead‐free double perovskites

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“Unleaded” Perovskites: Status Quo and Future Prospects of Tin‐Based Perovskite Solar Cells

Cited by 398 publications

References 217 publications

Stabilization of Inorganic CsPb0.5Sn0.5I2Br Perovskite Compounds by Antioxidant Tea Polyphenol

Stabilization of Inorganic CsPb0.5Sn0.5I2Br Perovskite Compounds by Antioxidant Tea Polyphenol

Metal Cations in Efficient Perovskite Solar Cells: Progress and Perspective

Ag/In lead‐free double perovskites

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Product

Resources

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Stabilization of Inorganic CsPb_0.5Sn_0.5I₂Br Perovskite Compounds by Antioxidant Tea Polyphenol

Stabilization of Inorganic CsPb_0.5Sn_0.5I₂Br Perovskite Compounds by Antioxidant Tea Polyphenol