Multifunctional Crosslinking‐Enabled Strain‐Regulating Crystallization for Stable, Efficient α‐FAPbI<sub>3</sub>‐Based Perovskite Solar Cells

Zhang, Hengkai; Chen, Zhiliang; Qin, Minchao; Ren, Zhiwei; Liu, Kuan; Huang, Jiaming; Shen, Dong; Wu, Zhenghao; Zhang, Yaokang; Hao, Jian; Lee, Chun‐Sing; Lu, Xinhui; Zheng, Zijian; Yu, Wei; Li, Gang

doi:10.1002/adma.202008487

Cited by 119 publications

(119 citation statements)

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“…Cl − has been demonstrated to improve the crystallization and reduce the non-radiative recombination of perovskites. 59,71,75–77 Methylenediammonium dichloride (MDACl 2 ), 27,28 MACl 29 and FACl 78 have already been introduced into α-FAPbI 3 . MACl is considered to be a transitional “stabilizer” that does not affect the crystal structure, and can induce the formation of α-FAPbI 3 .…”

Section: A Promising Photovoltaic Materials Of Fapbi3mentioning

confidence: 99%

“…This may be an effective structural stabilizer (inhibiting lattice deformation) and chemical stabilizer (enhancing the interaction between 3D grains) in FA-based perovskites. Recently, an in situ crosslinking-enabled strain-regulating crystallization (CSRC) method with trimethylolpropane triacrylate has been introduced to precisely regulate the top section of the perovskite film, where the largest lattice distortion occurs by Zhang et al 77 …”

Section: A Promising Photovoltaic Materials Of Fapbimentioning

confidence: 99%

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Development of formamidinium lead iodide-based perovskite solar cells: efficiency and stability

Zheng

Wang

et al. 2022

Chem. Sci.

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Section: A Promising Photovoltaic Materials Of Fapbi3mentioning

confidence: 99%

Section: A Promising Photovoltaic Materials Of Fapbimentioning

confidence: 99%

Development of formamidinium lead iodide-based perovskite solar cells: efficiency and stability

Zheng

Wang

et al. 2022

Chem. Sci.

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“…For example, Zhang et al proposed a crosslinking‐enabled strain‐regulating crystallization (CSRC) method, which inserted a cross‐linking agent, trimethylolpropane triacrylate (TMTA), to precisely adjust the lattice distortion at the top of the perovskite film (FAPbI 3 ) 0.95 (MAPbBr 3 ) 0.05 . [ 86 ] During the growth of perovskite, the crystal nuclei bonded with TMTA molecules were crosslinked with each other, which provided compression limit and balanced the overall thermal expansion of the crystal. Molecular crosslinking compression also “pulled” adjacent small perovskite particles together and promoted their merging into larger perovskite particles, as shown in Figure 8F.…”

Section: Improvement Of Fapbi3 Film Qualitymentioning

confidence: 99%

“…Compared with DMSO, NMP could form stronger coordination bonds to FAI in the perovskite precursor, which was beneficial to delay crystallization and generate large-grained perovskite films. 2020 [36] FTO/c-TiO 2021 [81] ITO/SnO 2021 [83] FTO/c-TiO 2 /m-TiO 2 /FAPbI [95] FTO/c-TiO 2 /m-TiO 2 / FAPbI 2017 [29] FTO/c-TiO 2019 [8] FTO/c-TiO 2 /m-TiO 2 /FAPbI 2021 [86] FTO/SnO 2021 [12] FTO/c-TiO 2 /m-TiO 2 / (FAPbI 3 ) 0.97 (MAPbBr 3 ) 0.03 /Spiro-OMeTAD/Au…”

Section: Precursor Conditionsmentioning

confidence: 99%

FAPbI₃ Perovskite Solar Cells: From Film Morphology Regulation to Device Optimization

Tang

et al. 2022

Solar RRL

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Organic–inorganic hybrid perovskite solar cells (PSCs) have attracted great attentions due to their rapid increase of power conversion efficiency (PCE). Although the highest PCE of PSCs (25.7%) has been achieved via using formamidinium lead iodide (FAPbI3) with a suitable bandgap, there is still a lack of systematic analysis on FAPbI3‐based PSCs toward high stability and high efficiency. Herein, the progress in FAPbI3 films and achievements in their high‐efficiency and long‐term stability PSCs are comprehensively reviewed. First, the progress from the aspects of morphology, defect, dimension, and strain for FAPbI3 film optimization is summarized and then the development of FAPbI3 PSCs in both efficiency and stability is discussed. Then, the methods to improve the FAPbI3 film quality by morphology control, defect passivation, dimensional regulation, and strain engineering, as well as strategies to optimize the device structure and interface layers, which are critical to promote device stability and efficiency, are evaluated. Finally, the outlook and strategies for realizing commercialized FAPbI3 PSCs with high efficiency and long lifetime are discussed.

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“…[30][31][32][33][34] COSs can be in situ crosslinked under certain conditions (such as UV light, heat, or initiators) to form an insoluble and stable polymer network, thereby freezing the perovskite morphology together with improved device stability. [35][36][37][38][39] For example, Li et al reported long-term operationable sound α-FAPbI 3 -based PerSCs through trimethylolpropane triacrylate crosslinking, which maintained 95% of initial PCE under long-term storage over 4000 h and 80% of initial PCE under light soaking for 1248 h. [40] In addition, an n-type conjugated molecule was used as an electron transport layer (ETL) on the top of perovskite to protect it from moisture and thermal, achieving considerable long-term stability. [32] While the design and application of organic molecules to realize crosslinking and coordination functions in PerSCs have been rarely studied, although it may be a facile and effective strategy to simultaneously improve the performance and stability of PerSCs.…”

Section: Introductionmentioning

confidence: 99%

Crosslinkable and Chelatable Organic Ligand Enables Interfaces and Grains Collaborative Passivation for Efficient and Stable Perovskite Solar Cells

et al. 2022

Small

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as a potential green energy-generating technology, proving to be a game-changer in photovoltaics. [1][2][3] Significant efforts, including material design, thin-film growth control, and interface engineering, have been devoted to promoting device performance. [4][5][6] Within only a few years, the power conversion efficiencies (PCEs) of single-junction PerSCs have been enhanced to 20% threshold. [7][8][9][10] Despite the leaps and bounds in efficiency, the stability of PerSCs, especially moisture/ water and thermal stability, is still a severe concern, since a long-term environmental atmosphere potentially makes degradation or phase transition of the perovskite. [11][12][13] Accordingly, device instability issues must be overcome along with the improvement of the PCE of PerSCs.Interface and grains control plays a vital role in achieving highly efficient and stable PerSCs. Nonradiative recombination caused by traps/defects existing at the interface and grain boundaries (GBs) impairs charge-density buildup and diminishes the photo-voltage of devices. [14][15][16] Moreover, these defects are the attack points of external factors such as water and thermal, resulting in the decomposition of perovskite. [17,18] Uncoordinated Pb 2+ ion is one typical ion defect on the surface and GBs of perovskite which seriously injures the device performance. [19] Previous studies have been carried out toward solving uncoordinated Pb 2+ ions in achieving high-efficiency PerSCs. [20] A series of organic molecules containing lone pair electrons on oxygen, sulfur, or nitrogen (such as pyridine, thiophene, benzoquinone, and crown ether) have been selected to reduce those defect sites by coordination bonds. [21][22][23] For instance, a series of crown ethers were employed to suppress uncoordinated surface defects, yielding an improved PCE exceeding 23% and achieving enhanced stability under ambient and operational conditions. [24] Moreover, as for the n-i-p structured PerSCs, SnO 2 has been regarded as a promising candidate for electron transport material. [25] However, surface traps/defects existing at the SnO 2 / perovskite interface are disadvantageous for charge transport. Therefore, optimizing the SnO 2 /perovskite interface to suppress the formation of surface traps/defects is vital to boosting device performance. [26,27] Generally, further modificationThe organic-inorganic halide perovskite solar cell (PerSC) is the state-of-theart emerging photovoltaic technology. However, the environmental water/ moisture and temperature-induced intrinsic degradation and phase transition of perovskite greatly retard the commercialization process. Herein, a dual-functional organic ligand, 4,7-bis((4-vinylbenzyl)oxy)-1,10-phenanthroline (namely, C1), with crosslinkable styrene side-chains and chelatable phenanthroline backbone, synthesized via a cost-effective Williamson reaction, is introduced for collaborative electrode interface and perovskite grain boundaries (GBs) engineering. C1 can chemically chelate with Sn 4+ in the SnO 2 electron transport...

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Multifunctional Crosslinking‐Enabled Strain‐Regulating Crystallization for Stable, Efficient α‐FAPbI₃‐Based Perovskite Solar Cells

Cited by 119 publications

References 43 publications

Development of formamidinium lead iodide-based perovskite solar cells: efficiency and stability

Development of formamidinium lead iodide-based perovskite solar cells: efficiency and stability

FAPbI₃ Perovskite Solar Cells: From Film Morphology Regulation to Device Optimization

Crosslinkable and Chelatable Organic Ligand Enables Interfaces and Grains Collaborative Passivation for Efficient and Stable Perovskite Solar Cells

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Multifunctional Crosslinking‐Enabled Strain‐Regulating Crystallization for Stable, Efficient α‐FAPbI3‐Based Perovskite Solar Cells

Cited by 119 publications

References 43 publications

Development of formamidinium lead iodide-based perovskite solar cells: efficiency and stability

Development of formamidinium lead iodide-based perovskite solar cells: efficiency and stability

FAPbI3 Perovskite Solar Cells: From Film Morphology Regulation to Device Optimization

Crosslinkable and Chelatable Organic Ligand Enables Interfaces and Grains Collaborative Passivation for Efficient and Stable Perovskite Solar Cells

Contact Info

Product

Resources

About

Multifunctional Crosslinking‐Enabled Strain‐Regulating Crystallization for Stable, Efficient α‐FAPbI₃‐Based Perovskite Solar Cells

FAPbI₃ Perovskite Solar Cells: From Film Morphology Regulation to Device Optimization