Kinetic Stabilization of the Sol–Gel State in Perovskites Enables Facile Processing of High‐Efficiency Solar Cells

Wang, Kai; Tang, Maochun; Dang, Hoang X.; Munir, Rahim; Barrit, Dounya; Bastiani, Michele De; Aydın, Erkan; Smilgies, Detlef‐M.; Wolf, Stefaan De; Amassian, Aram

doi:10.1002/adma.201808357

Cited by 92 publications

(141 citation statements)

References 50 publications

(61 reference statements)

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“…Moreover, a wide antisolvent processing window is beneficial to prepare reproducible MLMP films. [ 8,9 ] Therefore, MLMPs have been established as ideal candidates in PSCs with the remarkable PCE and long‐term stability.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Phosphorus‐Containing Lewis Acid and Base Passivation Enabling Efficient and Moisture‐Stable Perovskite Solar Cells

Yang

Dou

Kou

et al. 2020

Adv Funct Materials

175

139

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Multiple-cation lead mixed-halide perovskites (MLMPs) have been recognized as ideal candidates in perovskite solar cells in terms of high efficiency and stability due to decreased open-circuit voltage loss and suppressed yellow phase formation. However, they still suffer from an unsatisfactory long-term moisture stability. In this study, phosphorus-containing Lewis acid and base molecules are employed to improve device efficiency and stability based on their multifunction including recombination reduction, phase segregation suppression, and moisture resistance. The strong fluorine-containing Lewis acid treatment can achieve a champion PCE of 22.02%. Unencapsulated and encapsulated devices retain 63% and 80% of the initial efficiency after 14 days of aging under 75% and 85% relative humidity, respectively. The better passivation of Lewis acid implies more halide defects than Pb defects at the MLMP surface. This unbalanced defect type results from phase segregation that is the synergistic effect of Cs and halide ion migrations. Identifying defect type based on different passivation effects is beneficial to not only choose suitable passivators to boost the efficiency and slow down the moisture degradation of MLMP solar cells, but also to understand the mechanism of defect-assisted moisture degradation.

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Section: Introductionmentioning

confidence: 99%

Multifunctional Phosphorus‐Containing Lewis Acid and Base Passivation Enabling Efficient and Moisture‐Stable Perovskite Solar Cells

Yang

Dou

Kou

et al. 2020

Adv Funct Materials

175

139

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“…An antisolvent quench is also incorporated to intentionally control the exact nucleation time through the introduction of an antisolvent that supersaturates the precursor solution and removes excess precursor solvent . The antisolvent quench must happen within a specific nucleation window since quenching too early will not cause supersaturation and quenching after the film has already begun to nucleate will not induce the ideal nucleation site density . When the quenching occurs within this window, heterogeneous nucleation is promoted at the initial crystallization stage and minimizes pinholes in the resulting films .…”

Section: Introductionmentioning

confidence: 99%

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

Moot

Marshall

Wheeler

et al. 2020

Advanced Energy Materials

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The excellent optoelectronic properties demonstrated by hybrid organic/inorganic metal halide perovskites are all predicated on precisely controlling the exact nucleation and crystallization dynamics that occur during film formation. In general, high‐performance thin films are obtained by a method commonly called solvent engineering (or antisolvent quench) processing. The solvent engineering method removes excess solvent, but importantly leaves behind solvent that forms chemical adducts with the lead‐halide precursor salts. These adduct‐based precursor phases control nucleation and the growth of the polycrystalline domains. There has not yet been a comprehensive study comparing the various antisolvents used in different perovskite compositions containing cesium. In addition, there have been no reports of solvent engineering for high efficiency in all‐inorganic perovskites such as CsPbI3. In this work, inorganic perovskite composition CsPbI3 is specifically targeted and unique adducts formed between CsI and precursor solvents and antisolvents are found that have not been observed for other A‐site cation salts. These CsI adducts control nucleation more so than the PbI2–dimethyl sulfoxide (DMSO) adduct and demonstrate how the A‐site plays a significant role in crystallization. The use of methyl acetate (MeOAc) in this solvent engineering approach dictates crystallization through the formation of a CsI–MeOAc adduct and results in solar cells with a power conversion efficiency of 14.4%.

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“…Overall, this may result from the improved crystal quality during processing. [15,16] The second-order recombination rate constants, namely k 2 , are on the order of 10 À11 cm 3 s À1 . It should be noted that the photon reabsorption is not taken into account here, and this may cause underestimation of the second-order recombination.…”

Section: Charge Carrier Density-dependent Recombination Dynamicsmentioning

confidence: 99%

“…[12][13][14] This leads not only to increased performance, but also to better thermal stability and improved device reproducibility. [15,16] However, the precise reasons for these improvements are still unclear and fundamental studies of the effect of Cs/Rb-ion incorporation are scarce. In fact, most work to date has mainly focused on how the incorporation contributes to the stability of the perovskite phase and changes the perovskite's entropy, [12,14,17] whereas only few investigations have addressed the impact of incorporation of monovalent cations on the photophysics of lead halide perovskites.…”

Section: Introductionmentioning

confidence: 99%

Impact of Cesium/Rubidium Incorporation on the Photophysics of Multiple‐Cation Lead Halide Perovskites

Gao

Wang

et al. 2020

Solar RRL

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Incorporating cesium (Cs) or rubidium (Rb) cations into multiple‐cation lead mixed halide perovskites (FA0.83MA0.17Pb(I0.83Br0.17)3) increases their photovoltaic performance. Herein, the fundamental photophysics of perovskites are investigated by steady‐state and transient optical spectroscopy and the reasons for the performance increase are revealed. Cs/Rb‐cation incorporation slightly increases the bandgap, whereas exciton binding energies remain in the range of a few meV. Urbach energies are reduced, suggesting improved perovskite microstructure upon Cs/Rb incorporation. Carrier density‐induced broadening of the photo‐bleaching following the Burstein–Moss model is observed, and the effective carrier masses are determined to be a few tenths of the electron rest mass. From fits of the high‐energy tail of the perovskite's photo bleach to Boltzmann's distribution, subpicosecond hot‐carrier cooling is revealed, implying strong carrier–phonon coupling. Importantly, the charge carrier recombination dynamics indicate that Cs/Rb‐incorporation reduces both the first‐order (trap‐assisted) and the second‐order (radiative) recombination, which appears to be the main reason for the observed performance increase upon Cs/Rb‐cation incorporation. Overall, this work presents a detailed study of the photophysics of multiple‐cation mixed halide lead perovskites and develops a concise picture of the impact of cesium/rubidium incorporation on the photophysics and device performance.

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Kinetic Stabilization of the Sol–Gel State in Perovskites Enables Facile Processing of High‐Efficiency Solar Cells

Cited by 92 publications

References 50 publications

Multifunctional Phosphorus‐Containing Lewis Acid and Base Passivation Enabling Efficient and Moisture‐Stable Perovskite Solar Cells

Multifunctional Phosphorus‐Containing Lewis Acid and Base Passivation Enabling Efficient and Moisture‐Stable Perovskite Solar Cells

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

Impact of Cesium/Rubidium Incorporation on the Photophysics of Multiple‐Cation Lead Halide Perovskites

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