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14. Exploring the Critical Factors Toward Spectrally Stable Mixed‐Halide Blue Perovskite LEDs.

Author

Wei, Lulu, Tian, Shubing, Sun, Mingze, Song, Ruili, Wang, Yunhu, Zhang, Mingming, Wang, Lei, Wei, Zhanhua, and Xing, Jun

Abstract

Metal mixed‐halide perovskite has demonstrated considerable potential in the development of solution‐treated blue light‐emitting diodes (LEDs) with high external quantum efficiency, excellent color purity, and tunable wavelength. However, the severe phase segregation of mixed‐halide perovskite under bias voltage would lead to the spectral instability of LEDs. Therefore, suppressing phase segregation of Br/Cl perovskite towards spectrally stable blue perovskite LEDs (PeLEDs) is a big challenge. In this work, we systematically explore the influence of perovskite component, preparation conditions, and device structures on the spectral stability of PeLEDs. We have observed that the stable spectra increased the proportion of Cs in the A‐site cations, passivator, and the annealing temperature of perovskite films. Finally, we achieve a spectra‐stable and high‐performance blue PeLED under optimized conditions. Our findings provide important guidance for preparing spectrally stable PeLEDs. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Management of Triplet States in Modified Mononuclear Ruthenium(II) Complexes for Enhanced Photocatalysis.

Author

Liang, Ping, Wang, Zhaolong, Hao, Siwei, Chen, Kai‐Kai, Wu, Kaifeng, and Wei, Zhanhua

Subjects
ARTIFICIAL photosynthesis, HOMOGENEOUS catalysis, POLYCYCLIC aromatic hydrocarbons, TURNOVER frequency (Catalysis), PHOTOCATALYSTS
Abstract

Controlling the interplay between relaxation and charge/energy transfer processes in the excited states of photocatalysts is crucial for the performance of artificial photosynthesis. Metal‐to‐ligand charge‐transfer triplet states (3MLCT*) of ruthenium(II) complexes are broadly implemented for photocatalysis, but an effective means of managing the triplets for enhanced photocatalysis has been lacking. Herein, We proposed a strategy to considerably prolong the triplet excited‐state lifetime by decorating a ruthenium(II) phosphine complex (RuP‐1) with pendent polyaromatic hydrocarbons (PAHs). Systematic studies demonstrate that in RuP‐4 decorated with anthracene, sub‐picosecond electron transfer from anthracene to 3MLCT* leads to a charge‐separated state that can mediate the formation of the intra‐ligand triplet state (3IL) of anthracene, resulting in an exceptionally long excited‐state up to several milliseconds. This triplet management strategy enables impressive photocatalytic reduction of CO2 to CO with a turnover number (TON) of 404, an optimized quantum yield of 43 % and 100 % selectivity, which is the highest reported performance for mononuclear photocatalysts without additional photosensitizers. RuP‐4 also catalyzes photochemical hydrogen generation under argon. This work opens up an avenue for regulating the excited‐state charge/energy flow for the development of long‐lived 3IL multi‐functional mononuclear photocatalysts to boost artificial photosynthesis. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Quantitative Surface Passivation Through Drop‐on‐Demand Inkjet Printing Enables Highly Efficient Perovskite Solar Cells.

Author

Tan, Li, Jiang, Hengyi, Yang, Rui, Shen, Lina, Sun, Chao, Jin, Yongbin, Guan, Xiang, Song, Peiquan, Zheng, Lingfang, Tian, Chengbo, Xie, Liqiang, Yang, Jinxin, and Wei, Zhanhua

Subjects
SURFACE passivation, SOLAR cells, PEROVSKITE, ENERGY levels (Quantum mechanics), INK, SILICON solar cells, SURFACE defects
Abstract

Deposition of a passivation layer on top of the perovskite is proven to be an effective method for improving the efficiency and long‐term stability of perovskite solar cells (PSCs). And the spin‐coating method is the most typical and popular method developed for this purpose. However, the spin‐coating method wastes substantial passivator materials, thus the quantitative relationship between the passivator amount and the device performance cannot be obtained. Herein, a quantitative deposition method is developed through drop‐on‐demand inkjet printing to investigate the influence of 2‐adamantylamine hydrochloride (2‐ADAHCl) deposition surface density on the device performance, which is found to have a significant impact on the device performance. A low deposition surface density of 1.1 µg cm−2 does not reach its optimum passivation capability. In contrast, an excess deposition surface density of 10.1 µg cm−2 would lead to energy level mismatch and large series resistance at the perovskite/hole transport layer (HTL) interface, thus resulting in inferior device properties. At an optimum deposition surface density of 2.5 µg cm−2, perovskite surface defects are greatly suppressed, and the interfacial contact between perovskite and HTL is improved. Finally, PSCs with a high efficiency of 24.57% are achieved with improved operational and environmental stabilities. [ABSTRACT FROM AUTHOR]

Published
2024
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24. CsPb(IxBr1−x)3 solar cells

Author

Jia, Xue, Zuo, Chuantian, Tao, Shuxia, Sun, Kuan, Zhao, Yixin, Yang, Shangfeng, Cheng, Ming, Wang, Mingkui, Yuan, Yongbo, Yang, Junliang, Gao, Feng, Xing, Guichuan, Wei, Zhanhua, Zhang, Lijun, Yip, Hin-Lap, Liu, Mingzhen, Shen, Qing, Yin, Longwei, Han, Liyuan, Liu, Shengzhong, Wang, Lianzhou, Luo, Jingshan, Tan, Hairen, Jin, Zhiwen, and Ding, Liming

Published
2019
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26. 3D Crystal Framework Regulation Enables Se‐Functionalized Small Molecule Acceptors Achieve Over 19% Efficiency.

Author

Gao, Wei, Ma, Ruijie, Zhu, Lei, Li, Lang, Lin, Francis R., Dela Peña, Top Archie, Wu, Jiaying, Li, Mingjie, Zhong, Wenkai, Wu, Xuefei, Fink, Zachary, Tian, Chengbo, Liu, Feng, Wei, Zhanhua, Jen, Alex K.‐Y., and Li, Gang

Subjects
SMALL molecules, SOLAR cells, STERIC hindrance, POROSITY, PERMITTIVITY, POLYMER networks, COORDINATION polymers
Abstract

Se‐functionalized small molecule acceptors (SMAs) exhibit unique advantages in constructing materials with near‐infrared absorption, but their photovoltaic performance lags behind that of S‐containing analogs in organic solar cells (OSCs). Herein, two new Se‐containing SMAs, namely Se‐EH and Se‐EHp, are designed and synthesized by regulating bifurcation site of outer alkyl chain, which enables Se‐EH and Se‐EHp to form different 3D crystal frameworks from CH1007. Se‐EH displays tighter π–π stacking and denser packing framework with smaller‐sized pore structure induced by larger steric hindrance effect of outer alkyl chain branched at 2‐position, and a higher dielectric constant of PM6:Se‐EH active layer can be obtained. OSCs based on PM6:Se‐EH achieved very high PCEs of 18.58% in binary and 19.03% in ternary devices with a high FF approaching 80% for Se‐containing SMAs. A more significant alkyl chain steric hindrance effect in Se‐EH adjusts the molecular crystallization to form a favorable nanofiber interpenetrating network with an appropriate domain size to reduce rate of sub‐ns recombination and promote balanced transport of carriers. This work provides references for further design and development of highly efficient Se‐functionalized SMAs. [ABSTRACT FROM AUTHOR]

Published
2024
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27. Cross‐Linkable Fullerene Enables Elastic and Conductive Grain Boundaries for Efficient and Wearable Tin‐Based Perovskite Solar Cells.

Author

Hou, Enlong, Chen, Jingfu, Luo, Jiefeng, Fan, Yuteng, Sun, Chao, Ding, Yu, Xu, Peng, Zhang, Hui, Cheng, Shuo, Zhao, Xinjing, Xie, Liqiang, Yan, Jiawei, Tian, Chengbo, and Wei, Zhanhua

Subjects
SOLAR cells, CRYSTAL grain boundaries, PEROVSKITE, LIPOIC acid, YOUNG'S modulus, ELECTRON transport, FULLERENES
Abstract

Tin‐based perovskite solar cells (TPSCs) have received increasing attention due to their low toxicity, high theoretical efficiency, and potential applications as wearable devices. However, the inherent fast and uncontrollable crystallization process of tin‐based perovskites results in high defect density in the film. Meanwhile, when fabricated into flexible devices, the prepared perovskite film exhibits inevitable brittleness and high Young's modulus, seriously weakening the mechanical stability. In this work, we design and synthesize a cross‐linkable fullerene, thioctic acid functionalized C60 fulleropyrrolidinium iodide (FTAI), which has multiple interactions with perovskite components and can finely regulate the crystallization quality of perovskite film. The obtained perovskite film shows an increased grain size and a more matched energy level with the electron transport material, effectively improving the carrier extraction efficiency. The FTAI‐based rigid device achieves a champion efficiency of 14.91 % with enhanced stability. More importantly, the FTAI located at the perovskite grain boundaries could spontaneously cross‐link during the perovskite annealing process, which effectively improves the conductivity and elasticity of grain boundaries, thereby giving the film excellent bending resistance. Finally, the FTAI‐based wearable device yields a record efficiency of 12.35 % and displays robust bending durability, retaining about 90 % of the initial efficiency after 10,000 bending times. [ABSTRACT FROM AUTHOR]

Published
2024
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28. Boosting CsSnI3‐based near‐infrared perovskite light‐emitting diodes performance via solvent coordination engineering.

Author

Li, Yuqing, Guan, Xiang, Meng, Yuanyuan, Chen, Jingfu, Lin, Junpeng, Chen, Xi, Liu, Chia‐Yun, Zhao, Yaping, Zhang, Qin, Tian, Chengbo, Lu, Jianxun, and Wei, Zhanhua

Subjects
LIGHT emitting diodes, PEROVSKITE, QUANTUM efficiency, ENGINEERING, DENSITY of states, CRYSTALLIZATION, SOLVENTS
Abstract

Due to their unique photoelectric properties, nontoxic tin‐based perovskites are emerging candidates for efficient near‐infrared LEDs. However, the facile oxidation of Sn2+ and the rapid crystallization rate of tin‐based perovskites result in suboptimal film quality, leading to inferior efficiencies of tin‐based perovskite light‐emitting diodes (Pero‐LEDs). In this study, we investigate the influence of commonly used solvents on the quality of the CsSnI3 films. Remarkably, DMSO exhibits a stronger interaction with SnI2, forming a stable intermediate phase of SnI2·3DMSO. This intermediate effectively inhibits the oxidation of Sn2+ and slows down the crystallization rate, bringing in lower defect state density and higher photoluminescence quantum yield of the prepared perovskite films. Consequently, the corresponding Pero‐LEDs achieve a maximum external quantum efficiency (EQE) of 5.6%, among the most efficient near‐infrared Pero‐LEDs. In addition, the device processes ultra‐low efficiency roll‐off and high reproducibility. Our research underscores the crucial role of solvent‐perovskite coordination in determining film quality. These findings offer valuable guidance for screening solvents to prepare highly efficient and stable tin‐based perovskites. [ABSTRACT FROM AUTHOR]

Published
2024
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29. Bi‐Functional Phosphine Oxide Passivator for Efficient Near‐Infrared Sn‐Based Perovskite Light‐Emitting Diodes with Ultra‐Low Efficiency Roll‐Off.

Author

Meng, Yuanyuan, Guan, Xiang, Weng, Yalian, Lu, Jianxun, Li, Yuqing, Zhao, Yaping, Li, Mingliang, Feng, Wenjing, Sun, Chao, Lin, Junpeng, and Wei, Zhanhua

Subjects
LIGHT emitting diodes, PHOSPHINE oxides, PEROVSKITE, CHARGE injection, QUANTUM efficiency, ELECTRON transport, PASSIVATION
Abstract

Recently, lead‐free Sn‐based perovskite light‐emitting diodes (PeLEDs) have attracted wide attention due to their near‐infrared emission and environmental friendliness. However, desired Sn2+ is easily oxidized to Sn4+ in the crystallization process, resulting in defects and intrinsically p‐doped properties in the perovskite films. The uncontrollable oxidation affects the charge injection balance and radiative recombination, leading to poor device performance. Herein, a bi‐functional conductive molecular, 2,7‐bis(diphenylphosphoryl)‐9,9′‐spirobifluorene (SPPO13) with two P═O functional groups, is used to interact with perovskite to passivate defects and suppress the oxidation of Sn2+. Moreover, the SPPO13 modification layer inserted between the perovskite emitter and the electron transport layer can regulate the carrier injection and transport, thus promoting the charge balance. As a result, the high‐performance near‐infrared CsSnI3 PeLEDs with a record external quantum efficiency (EQE) of 6.60% and ultra‐low efficiency roll‐off are achieved. The work provides a novel approach to regulate defect passivation and charge transport for efficient Sn‐based PeLEDs. [ABSTRACT FROM AUTHOR]

Published
2024
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30. Efficient Perovskite Light‐Emitting Diodes Enabled by Nickel Acetate Interlayer.

Author

Zhang, Qin, Zhao, Yaping, Qin, Xiangqian, Li, Mingliang, Sun, Haoran, Zhou, Peng, Feng, Wenjing, Li, Yuqing, Lu, Jianxun, Lin, Kebin, Shi, Lei, and Wei, Zhanhua

Subjects
LIGHT emitting diodes, NICKEL, ACETATES, PEROVSKITE, QUANTUM efficiency, METAL halides
Abstract

Metal halide perovskite light‐emitting diodes (Pero‐LEDs) have gained great attention due to their promising applications in lighting and displays. However, in their conventional three‐layered sandwich structure, some undeserved carrier behaviors, such as imbalanced carrier injection, severe carrier loss, and unstable recombination zone, limit the device's performance. Herein, a four‐layered design by inserting a nickel acetate (Ni(OAc)2) interlayer between the emitter and hole‐transport layer(HTL) to manage carrier behavior and improve radiative recombination efficiency is proposed. Specifically, the Ni(OAc)2 interlayer is poorly conductive and can partially block the hole injection, making the hole‐electron injection more balanced. And the Ni(OAc)2 interlayer avoids the direct contact between the perovskite emitter and hole transporter, reducing the interfacial carrier quenching. Moreover, the Ni(OAc)2 interlayer inhibits the electron‐migrated recombination at the hole transporter interface, confining the carrier recombination zone in the emitter layer. As a result, the corresponding Pero‐LEDs achieve a maximum external quantum efficiency (EQEmax) of 24.6% with good reproducibility, showing an average EQEmax of over 20%. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Chlorofullerene C60Cl6 Enables Efficient and Stable Tin‐Based Perovskite Solar Cells.

Author

Chen, Jingfu, Tian, Chengbo, Sun, Chao, Yang, Panpan, Feng, Wenjing, Zheng, Lingfang, Yang, Liu, Hou, Enlong, Luo, Jiefeng, Xie, Liqiang, and Wei, Zhanhua

Subjects
SOLAR cells, PEROVSKITE, CRYSTAL grain boundaries, OXYGEN in water
Abstract

Tin‐based perovskite solar cells (TPSCs) have received great attention due to their eco‐friendly properties and high theoretical efficiencies. However, the fast crystallization feature of tin‐based perovskites leads to poor film quality and limits the corresponding device performance. Herein, a chlorofullerene, C60Cl6, with six chlorine attached to the C60 cage, is applied to modulate the crystallization process and passivate grain boundary defects of the perovskite film. The chemical interactions between C60Cl6 and perovskite components retard the transforming process of precursors to perovskite crystals and obtain a high‐quality tin‐based perovskite film. It is also revealed that the C60Cl6 located at the surfaces and grain boundaries can not only passivate the defects but also offer a role in suturing grain boundaries to suppress the detrimental effects of water and oxygen on perovskite films, especially the oxidation of Sn2+ to Sn4+. As a result, the C60Cl6‐based device yields a remarkably improved device efficiency from 10.03% to 13.30% with enhanced stability. This work provides a new strategy to regulate the film quality and stability of TPSCs using functional fullerene materials. [ABSTRACT FROM AUTHOR]

Published
2024
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36. Regulating Orientational Crystallization and Buried Interface for Efficient Perovskite Solar Cells Enabled by a Multi‐Fluorine‐Containing Higher Fullerene Derivative.

Author

Song, Peiquan, Hou, Enlong, Liang, Yuming, Luo, Jiefeng, Xie, Liqiang, Qiu, Jianhang, Tian, Chengbo, and Wei, Zhanhua

Subjects
SOLAR cells, FULLERENE derivatives, PEROVSKITE, CRYSTALLIZATION, ION migration & velocity, ION energy, ELECTRON transport
Abstract

Perovskite films prepared by the solution process usually result in irregular grain orientation and rich buried interface defects, hindering the further improvement of device performance. Herein, multi‐fluorine‐containing C60‐ and C70 (higher fullerene)‐porphyrin derivatives, F60PD and F70PD, are synthesized and pre‐buried to modify the SnO2/perovskite heterointerface. The F70PD modification layer provides a better perovskite quality and more effective electron transporting capability compared to the corresponding F60PD, with the F70PD being more effective in regulating the perovskite growth, passivating the buried interface defects, and optimizing the interface energy level alignment. Consequently, the F70PD‐based device delivers superior efficiency and stability than the control and F60PD‐based devices. The F70PD‐based device yields a champion efficiency of 24.09% with negligible hysteresis. Meanwhile, due to the increased activation energy of ion migration, the F70PD‐based device maintains 80% of its initial efficiency after operating at the maximum power point for 1620 h. This study highlights the potential of designing higher fullerene materials for buried interface to further improve the perovskite solar cells' performance. [ABSTRACT FROM AUTHOR]

Published
2023
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37. Versatile and High‐Performance LiTaO3:Tb3+, Gd3+ Perovskite for Multimode Anti‐counterfeiting, Flexible X‐Ray Imaging, Continuous Stress Sensing, and Non‐Real‐Time Recording.

Author

Lyu, Tianshuai, Dorenbos, Pieter, and Wei, Zhanhua

Subjects
X-ray imaging, OPTICALLY stimulated luminescence, PEROVSKITE, THERMOLUMINESCENCE, LUMINESCENCE, GAMMA ray bursts, CHARGE carriers
Abstract

Multimode luminescence relates to how charge carriers are transported and recombined in response to various physical excitations. It shows promising applications in many fields like advanced anti‐counterfeiting, information storage and encryption. Enabling a stable single compound with multimode luminescence is a unique technology but still remains a challenge. Herein, a versatile and high‐performance energy storage LiTaO3:0.01Tb3+,xGd3+ perovskite is discovered by utilizing the interplay of electron‐trapping defect levels and hole‐trapping Tb3+. It combines an excellent charge carrier storage capacity (≈7 and 12 times higher than state‐of‐the‐art BaFBr(I):Eu2+ and Al2O3:C), >1200 h storage duration, >40 h afterglow, efficient optically stimulated luminescence, persistent mechanoluminescence, and force‐induced charge carrier storage features. Particularly, it well responds to various stimuli channels, i.e., wide‐range X‐rays to 850 nm infrared photons, thermal activation, mechanical force grinding, or compression. To elucidate this multimode luminescence, charge carrier trapping and release processes in LiTaO3:0.01Tb3+,xGd3+ with various physical stimulations will be unraveled by combining the vacuum‐referred binding diagram construction, spectroscopy, thermoluminescence, and mechanoluminescence techniques. The versatile and high‐performance LiTaO3:0.01Tb3+,xGd3+ enables promising proof‐of‐concept multimode luminescence applications in advanced anti‐counterfeiting, flexible X‐ray imaging, continuous compression force sensing, and non‐real‐time recording. [ABSTRACT FROM AUTHOR]

Published
2023
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40. Reducing the Surface Reactivity of Alkyl Ammonium Passivation Molecules Enables Highly Efficient Perovskite Solar Cells.

Author

Zheng, Lingfang, Shen, Lina, Fang, Zheng, Song, Peiquan, Tian, Wanjia, Chen, Jingfu, Liu, Kaikai, Luo, Yujie, Xu, Peng, Yang, Jinxin, Tian, Chengbo, Xie, Liqiang, and Wei, Zhanhua

Subjects
SOLAR cells, PASSIVATION, SURFACE passivation, SURFACE analysis, OPEN-circuit voltage, PEROVSKITE
Abstract

The non‐radiative recombination at the interfaces of perovskite solar cells (PSCs) is a crucial issue that limits the efficiency and stability of the devices. State‐of‐the‐art surface passivation strategies usually utilize alkyl ammonium halides to suppress the non‐radiative recombination of PSCs, but their high surface reactivity leads to the transformation into 2D perovskites under working conditions, limiting the passivation effect and the charge transport of PSCs. Herein, a non‐halide ionic salt 1‐naphthylmethylammonium formate (NMACOOH) is synthesized for surface passivation of perovskite films. In contrast to the traditional 1‐naphthylmethylammonium iodide, NMACOOH treatment hinders the formation of 2D perovskite and forms a thermally stable PbI2‐NMACOOH adduct on the perovskite surface. Surface characterization reveals that NMA+ can passivate the cation vacancies of the 3D perovskite while HCOO− passivates the metallic Pb0 and halide‐vacancy defects. Therefore, the non‐radiative recombination of PSCs is dramatically suppressed and a high open‐circuit voltage of 1.19 V is obtained. Finally, PSCs with high efficiency of 24.75% and improved long‐term stability (98% of the initial efficiency after 1800‐h storage) are obtained. Moreover, the NMACOOH‐passivated devices also show robust operational stability, retaining 83% of the initial efficiency after working for 658 h under continuous one‐sun illumination. [ABSTRACT FROM AUTHOR]

Published
2023
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44. Dissolved-Cl2 triggered redox reaction enables high-performance perovskite solar cells.

Author

Luo, Yujie, Liu, Kaikai, Yang, Liu, Feng, Wenjing, Zheng, Lingfang, Shen, Lina, Jin, Yongbin, Fang, Zheng, Song, Peiquan, Tian, Wanjia, Xu, Peng, Li, Yuqing, Tian, Chengbo, Xie, Liqiang, and Wei, Zhanhua

Subjects
SOLAR cells, OXIDATION-reduction reaction, PEROVSKITE, SURFACE passivation, HETEROJUNCTIONS
Abstract

Constructing 2D/3D perovskite heterojunctions is effective for the surface passivation of perovskite solar cells (PSCs). However, previous reports that studying perovskite post-treatment only physically deposits 2D perovskite on the 3D perovskite, and the bulk 3D perovskite remains defective. Herein, we propose Cl2-dissolved chloroform as a multifunctional solvent for concurrently constructing 2D/3D perovskite heterojunction and inducing the secondary growth of the bulk grains. The mechanism of how Cl2 affects the performance of PSCs is clarified. Specifically, the dissolved Cl2 reacts with the 3D perovskite, leading to Cl/I ionic exchange and Ostwald ripening of the bulk grains. The generated Cl further diffuses to passivate the bulk crystal and buried interface of PSCs. Hexylammonium bromide dissolved in the solvent reacts with the residual PbI2 to form 2D/3D heterojunctions on the surface. As a result, we achieved high-performance PSCs with a champion efficiency of 24.21% and substantially improved thermal, ambient, and operational stability. Constructing 2D/3D perovskite heterojunctions is effective for the surface passivation of perovskite solar cells. Here, the authors apply Cl2-dissolved chloroform as a multifunctional solvent and achieve a champion device efficiency of 24.21% with improved thermal, ambient and operational stability. [ABSTRACT FROM AUTHOR]

Published
2023
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46. Halogenated Hole‐Transport Molecules with Enhanced Isotropic Coordination Capability Enable Improved Interface and Light Stability of Perovskite Solar Cells.

Author

Zhang, Zheng, Shen, Lina, Wang, Sijing, Zheng, Lingfang, Li, Da, Li, Zhijun, Xing, Yifan, Guo, Kunpeng, Xie, Liqiang, and Wei, Zhanhua

Subjects
SOLAR cells, INTERFACE stability, PEROVSKITE, MOLECULAR orientation, OPEN-circuit voltage, COORDINATION polymers
Abstract

Interfacial defects are one of the main origins of the hysteresis effect and limit the efficiency and light stability of perovskite solar cells (PSCs). Herein, the authors propose to grant the hole‐transport materials' (HTMs) improved isotropic coordination and defect passivation through simple halogenation, enabling a robust perovskite/hole‐transport layer interface while avoiding the use of an external passivation layer. First‐principles simulations and experimental results show that the halogenated HTMs offer more isotropic coordination sites for Pb2+ ions than the halogen‐free ones, thus providing the enhanced passivating ability of defects regardless of their molecular orientation at the surface of perovskite films. Consequently, the PSCs based on the chlorinated spiro[fluorene‐9,9′‐xanthene]‐based HTM show suppressed nonradiative recombination, delivering a remarkable open‐circuit voltage (VOC) enhancement (from 1.07 to 1.14 V) and a minimal hysteresis index of as low as 0.07%. The corresponding cells also show much improved light stability, retaining 81% of the initial efficiency after 1000 h of continuous illumination at the maximum power point. This work demonstrates that a solid isotropic coordination capability of HTMs with Pb2+ is critical to forming a robust interface and improving the PSCs' light stability. [ABSTRACT FROM AUTHOR]

Published
2023
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