Atomic Layer Engineering of Aluminum‐Doped Zinc Oxide Films for Efficient and Stable Perovskite Solar Cells

Kruszyńska, Joanna; Ozkaya, Veysel; Surucu, Belkis; Szawcow, Oliwia; Nikiforow, Kostiantyn; Hołdyński, Marcin; Tavakoli, Mohammad Mahdi; Yadav, Pankaj; Kot, Małgorzata; Kołodziej, Grzegorz; Wlazło, Mateusz; Satapathi, Soumitra; Akın, Seçkin; Prochowicz, Daniel

doi:10.1002/admi.202200575

Cited by 24 publications

(23 citation statements)

References 77 publications

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“…conducted a study on the characteristics of ETL and device stability by controlling the termination of the AZO layer. [ 142 ] Consequently, the perovskite solar cells with a controlled ALD–AZO layer showed better moisture stability than ZnO‐based perovskite solar cells, which maintained more than 80% of initial efficiency after 100 h under 40% relative humidity without encapsulation. Although the ALD technique has not yet been applied in the PQD solar cell field, it has been used in other optoelectronic devices, such as LEDs.…”

Section: Device Viewpoints On the Stability Of Cspbi3 Pqd Solar Cellsmentioning

confidence: 99%

Key Factors Affecting the Stability of CsPbI₃ Perovskite Quantum Dot Solar Cells: A Comprehensive Review

et al. 2022

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to a power conversion efficiency (PCE) of 25.7%. [12] However, their low stability under environmental stress has been considered a major obstacle to their commercialization. [13] Organic-inorganic LHPs with an APbI 3 structure are easily decomposed into PbI 2 and other organic compounds due to volatile organic A-site cations, such as methylammonium (MA) and formamidinium (FA). [14,15] To address this issue, several strategies have been proposed, such as grain boundary passivation and the introduction of large organic cations into the A-site. [16] Meanwhile, replacing organic cations with robust inorganic cations can enhance thermal stability. From this point of view, all-inorganic perovskites without volatile organic components have attracted interest as alternative materials to organicinorganic LHPs. [17,18] In particular, all-inorganic CsPbI 3 perovskites are promising materials for solar cell applications, demonstrating charge-carrier mobilities comparable to those of organic-inorganic LHPs, a bandgap of 1.73 eV, and a PCE over 20%. [19] Despite the impressive thermal stability of all-inorganic LHPs, they undergo thermodynamic phase transition under device operation conditions. Unfortunately, photoactive cubic CsPbI 3 perovskites are easily converted to the photoinactive orthorhombic phase at room temperature (RT) because they are stable at temperatures above 300 °C. [17,20] Due to this thermodynamic phase instability, it is challenging to fabricate stable cubic CsPbI 3 perovskite films at RT. To address this issue, in 2015, Kovalenko et al. reduced the crystal size of CsPbI 3 perovskites to the nanoscale. [21] Crystal size and surface energy affect phase stability, and it was demonstrated that the crystal size reduced to the nanoscale can enhance the contribution of surface energy, stabilizing the cubic phase of CsPbI 3 perovskites. [21][22][23] From this perspective, CsPbI 3 perovskite quantum dots (PQDs) with a few nanometers in size can demonstrate high cubic phase stability and be utilized at RT. [24,25] Adding to strong cubic phase stability, CsPbI 3 PQDs have great advantages for solar cell applications. For example, CsPbI 3 PQDs have defect tolerance, which enables a high photoluminescence quantum yield up to a near unity without outer shelling and leads to low open-circuit voltage loss in solar cells compared to bulk perovskites. [26,27] Furthermore, CsPbI 3 PQDs enable the fabrication of a thick absorber layer without a thermal annealing process. The power conversion efficiency ofCsPbI 3 perovskite quantum dot (PQD) solar cells shows increase from 10.77% to 16.2% in a short period owing to advances in material and device design for solar cells. However, the device stability of CsPbI 3 PQD solar cells remains poor in ambient conditions, which requires an in-depth understanding of the degradation mechanisms of CsPbI 3 PQDs solar cells in terms of both inherent material properties and device characteristics. Along with this analysis, advanced strategies to overcome poor device stability must be concei...

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Section: Device Viewpoints On the Stability Of Cspbi3 Pqd Solar Cellsmentioning

confidence: 99%

Key Factors Affecting the Stability of CsPbI₃ Perovskite Quantum Dot Solar Cells: A Comprehensive Review

et al. 2022

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“…However, it was later corroborated by researchers that the hysteresis index of a solar cell somehow originates from its intrinsic properties, rather than the scan rates or direction of the applied bias. Amongst them, the ferroelectric and large dielectric properties of perovskite sensitizers at the nano-scale [34,134], the interfacial ferroelectric characteristics of the device [18], ion migration [35,36], mismatched energy band alignment of the device layers [38,39], slower trapping-detrapping of charges at the grain boundaries or the barriers of different layers [40,135], inefficient charge transportation or extraction by ETLs and HTLs [42,43], imbalance in the charge transport through HTLs and ETLs [44,45], various structural or chemical changes of the involved materials (e.g., perovskite absorber, ETL, and HTL) during operation or in response to various hostile environmental parameters such as temperature and humidity [134,136], undesirable charge trapping at the defect sites of different layers of the device created by such deteriorations [137,138], etc., are attributed to such anomalous PSC device behavior. Some researchers even mentioned it as a light-induced hysteresis in solar cell devices [35,129,139].…”

Section: Hysteresis Problem Of Perovskitementioning

confidence: 99%

“…The reason behind such PV behavior is still unknown. However, researchers have attributed several factors to it, such as the large dielectric properties of perovskite sensitizers at the nano-scale [33,34], interfacial ferroelectric characteristics of the device [15], ion-migration [35][36][37], mismatched energy band alignment of the device layers [38,39], the slower trapping-detrapping of charges at the grain boundaries or the barriers of different layers [40,41], inefficient charge transportation or extraction by ETLs and HTLs [42,43], and imbalance in the charge transport through HTLs and ETLs [44,45], etc.…”

Section: Introductionmentioning

confidence: 99%

Recent Criterion on Stability Enhancement of Perovskite Solar Cells

et al. 2022

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Perovskite solar cells (PSCs) have captured the attention of the global energy research community in recent years by showing an exponential augmentation in their performance and stability. The supremacy of the light-harvesting efficiency and wider band gap of perovskite sensitizers have led to these devices being compared with the most outstanding rival silicon-based solar cells. Nevertheless, there are some issues such as their poor lifetime stability, considerable J–V hysteresis, and the toxicity of the conventional constituent materials which restrict their prevalence in the marketplace. The poor stability of PSCs with regard to humidity, UV radiation, oxygen and heat especially limits their industrial application. This review focuses on the in-depth studies of different direct and indirect parameters of PSC device instability. The mechanism for device degradation for several parameters and the complementary materials showing promising results are systematically analyzed. The main objective of this work is to review the effectual strategies of enhancing the stability of PSCs. Several important factors such as material engineering, novel device structure design, hole-transporting materials (HTMs), electron-transporting materials (ETMs), electrode materials preparation, and encapsulation methods that need to be taken care of in order to improve the stability of PSCs are discussed extensively. Conclusively, this review discusses some opportunities for the commercialization of PSCs with high efficiency and stability.

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“…[5,[42][43][44][45][46][47][48][49] Remarkably, the state-of-the-art PCE (22.6%) among reported low-temperature processed PSCs was achieved for a device based on a sol-gel-derived ZnO layer modified by potassium chloride. [36] On the other hand, to avoid the participation of organic ligand in the synthetic process and/ or negligible organic impurities in the resulting ZnO films, alternative strategies for ZnO film growth by an atomic layer deposition (Table S1, entry 22, Supporting Information), [50] and a solution-processed combustion synthesis (Table S1, entry 21, Supporting Information, ) [31] were developed. The latter novel combustion synthetic approach delivered PSCs of remarkable PCEs of 18.82% and 19.84% for Cs 0.05 FA 0.81 MA0.…”

Section: Introductionmentioning

confidence: 99%

Organic Ligand‐Free ZnO Quantum Dots for Efficient and Stable Perovskite Solar Cells

Chavan

Wolska‐Pietkiewicz

Prochowicz

et al. 2022

Adv Funct Materials

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Zinc oxide (ZnO) is a promising electron‐transport layer (ETL) in thin‐film photovoltaics. However, the poor chemical compatibility between commonly used sol–gel‐derived ZnO nanostructures and organo–metal halide perovskites makes it highly challenging to obtain efficient and stable perovskite solar cells (PSCs). Here, a novel approach is reported for low‐temperature processed pure ZnO ETLs for planar heterojunction PSCs based on ZnO quantum dots (QDs) stabilized by dimethyl sulfoxide (DMSO) as easily removable solvent molecules. With no need for the ETL doping or surface modification, the champion PSC comprising the mixed‐cation and mixed‐halide Cs5(MA0.17FA0.83)95Pb(I0.83Br0.17)3 absorber layer reaches a maximum power conversion efficiency of 20.05%, which is significantly higher than that obtained for a reference device based on a standard sol–gel‐derived ZnO nanostructured layer (17.78%). Thus, along with the observed better operational stability in ambient conditions and elevated temperature, the champion device achieves the state‐of‐the‐art performance among reported non‐passivated pure ZnO ETL‐based PSCs. The improved photovoltaic performance is attributed to both a higher uniformity of the surface morphology and a lower defects density of films based on the organometallic‐derived QDs that are likely to ensure the enhanced stability of the ZnO/perovskite interface.

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Atomic Layer Engineering of Aluminum‐Doped Zinc Oxide Films for Efficient and Stable Perovskite Solar Cells

Cited by 24 publications

References 77 publications

Key Factors Affecting the Stability of CsPbI₃ Perovskite Quantum Dot Solar Cells: A Comprehensive Review

Key Factors Affecting the Stability of CsPbI₃ Perovskite Quantum Dot Solar Cells: A Comprehensive Review

Recent Criterion on Stability Enhancement of Perovskite Solar Cells

Organic Ligand‐Free ZnO Quantum Dots for Efficient and Stable Perovskite Solar Cells

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Atomic Layer Engineering of Aluminum‐Doped Zinc Oxide Films for Efficient and Stable Perovskite Solar Cells

Cited by 24 publications

References 77 publications

Key Factors Affecting the Stability of CsPbI3 Perovskite Quantum Dot Solar Cells: A Comprehensive Review

Key Factors Affecting the Stability of CsPbI3 Perovskite Quantum Dot Solar Cells: A Comprehensive Review

Recent Criterion on Stability Enhancement of Perovskite Solar Cells

Organic Ligand‐Free ZnO Quantum Dots for Efficient and Stable Perovskite Solar Cells

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Product

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Key Factors Affecting the Stability of CsPbI₃ Perovskite Quantum Dot Solar Cells: A Comprehensive Review

Key Factors Affecting the Stability of CsPbI₃ Perovskite Quantum Dot Solar Cells: A Comprehensive Review