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References (78)
-
M. Saidaminov, I. Spanopoulos, Jehad Abed, Weijun Ke, Joshua Wicks, M. Kanatzidis, E. Sargent (2020)
Conventional Solvent Oxidizes Sn(II) in Perovskite InksACS energy letters, 5
-
Gardner K. L. (2016)
1600386Adv. Energy Mater., 6
-
Keyou Yan, M. Long, Tiankai Zhang, Zhanhua Wei, Haining Chen, Shihe Yang, Jianbin Xu (2015)
Hybrid halide perovskite solar cell precursors: colloidal chemistry and coordination engineering behind device processing for high efficiency.Journal of the American Chemical Society, 137 13
-
Kaicheng Zhang, A. Späth, Osbel Almora, Vincent Corre, Jonas Wortmann, Jiyun Zhang, Zhiqiang Xie, A. Barabash, Maria Hammer, Thomas Heumüller, J. Min, Rainer Fink, L. Lüer, Ning Li, C. Brabec (2022)
Suppressing Nonradiative Recombination in Lead–Tin Perovskite Solar Cells through Bulk and Surface Passivation to Reduce Open Circuit Voltage LossesACS Energy Letters
-
Yan K. (2015)
4460J. Am. Chem. Soc., 137
-
Diego Girolamo, Jorge Pascual, M. Aldamasy, Z. Iqbal, Guixiang Li, Eros Radicchi, Meng-Yu Li, Silver‐Hamill Turren‐Cruz, G. Nasti, A. Dallmann, F. Angelis, A. Abate (2021)
Solvents for Processing Stable Tin Halide PerovskitesACS energy letters, 6
-
Jinhui Tong, Qi Jiang, A. Ferguson, Axel Palmstrom, Xiaoming Wang, Ji Hao, Sean Dunfield, Amy Louks, S. Harvey, Chongwen Li, Haipeng Lu, R. France, Samuel Johnson, Fei Zhang, Mengjin Yang, J. Geisz, M. McGehee, M. Beard, Yanfa Yan, D. Kuciauskas, J. Berry, K. Zhu (2022)
Carrier control in Sn–Pb perovskites via 2D cation engineering for all-perovskite tandem solar cells with improved efficiency and stabilityNature Energy, 7
-
Zhang Z. (2022)
165Nano‐Micro Lett., 14
-
Wu X. (2022)
122Mater. Horiz., 10
-
Heng-Jian Li, Tongle Bu, Jing Li, Zhipeng Lin, Junye Pan, Qianhui Li, Xiaoli Zhang, Zhiliang Ku, Yi-bing Cheng, Fuzhi Huang (2021)
Ink Engineering for Blade Coating FA-Dominated Perovskites in Ambient Air for Efficient Solar Cells and Modules.ACS applied materials & interfaces
-
Gavrilin M. V. (2000)
490Pharm. Chem. J., 34
-
Zhang Z. (2022)
3605J. Mater. Chem. A, 10
-
Wang J. (2022)
2203886Small, 18
-
Renxing Lin, K. Xiao, Zhengyuan Qin, Qiaolei Han, Chunfeng Zhang, Mingyang Wei, M. Saidaminov, Yuan Gao, Jun Xu, M. Xiao, Aidong Li, Jia Zhu, E. Sargent, H. Tan (2019)
Monolithic all-perovskite tandem solar cells with 24.8% efficiency exploiting comproportionation to suppress Sn(ii) oxidation in precursor inkNature Energy, 4
-
Yeom K. W. (2022)
2202496Adv. Energy Mater., 12
-
Eun Kim, June Lee, S. Kim, J. Gu, Donghwa Lee (2021)
A-Site Effect on the Oxidation Process of Sn-Halide Perovskite: First-Principles Calculations.The journal of physical chemistry letters
-
Qiqi Zhang, Guorong Ma, K. Green, Kristine Gollinger, Jaiden Moore, Teresa Demeritte, P. Ray, Glake Hill, X. Gu, S. Morgan, Manliang Feng, Santanu Banerjee, Qilin Dai (2022)
FAPbI3 Perovskite Films Prepared by Solvent Self-Volatilization for Photovoltaic ApplicationsACS Applied Energy Materials
-
Fang X. (2017)
842J. Mater. Chem. C, 5
-
Hamill J. C. (2018)
92ACS Energy Lett., 3
-
Rahimnejad S. (2016)
2795ChemPhysChem, 17
-
Xu Z. (2003)
3632Chem. Mater., 15
-
Pu Wu, Jin Wen, Yurui Wang, Z. Liu, Renxing Lin, Hongjiang Li, Haowen Luo, H. Tan (2022)
Efficient and Thermally Stable All‐Perovskite Tandem Solar Cells Using All‐FA Narrow‐Bandgap Perovskite and Metal‐oxide‐based Tunnel JunctionAdvanced Energy Materials, 12
-
Yan N. (2022)
2201384Adv. Funct. Mater., 32
-
Nan Yan, X. Ren, Z. Fang, Xiao-Fang Jiang, Zhuo Xu, Lu Zhang, S. Ren, Lingbo Jia, Jingru Zhang, Yachao Du, Dewei Zhao, Kui Zhao, Shangfeng Yang, S. Liu (2022)
Ligand‐Anchoring‐Induced Oriented Crystal Growth for High‐Efficiency Lead‐Tin Perovskite Solar CellsAdvanced Functional Materials, 32
-
Zhang Q. (2022)
1487ACS Appl. Energy Mater., 5
-
Di Girolamo D. (2021)
959ACS Energy Lett., 6
-
Jošt M. (2020)
1904102Adv. Energy Mater., 10
-
Zhang K. (2022)
3235ACS Energy Lett., 7
-
Hanul Min, Do Lee, Junu Kim, Gwisu Kim, K. Lee, Jongbeom Kim, M. Paik, Young Kim, Kwang Kim, M. Kim, T. Shin, Sang Seok (2021)
Perovskite solar cells with atomically coherent interlayers on SnO2 electrodesNature, 598
-
S. Rahimnejad, A. Kovalenko, Sergio Forés, C. Aranda, Antonio Guerrero (2016)
Coordination Chemistry Dictates the Structural Defects in Lead Halide Perovskites.Chemphyschem : a European journal of chemical physics and physical chemistry, 17 18
-
Zhanfei Zhang, Jianghu Liang, Jianli Wang, Yiting Zheng, Xueyun Wu, Congcong Tian, Anxin Sun, Zhenhua Chen, Chun‐Chao Chen (2022)
Resolving Mixed Intermediate Phases in Methylammonium-Free Sn–Pb Alloyed Perovskites for High-Performance Solar CellsNano-Micro Letters, 14
-
Shasha Zhang, Shaohang Wu, Weitao Chen, Hongmei Zhu, Z. Xiong, Zhichun Yang, Chuanliang Chen, Rui Chen, Liyuan Han, Wei Chen (2018)
Solvent engineering for efficient inverted perovskite solar cells based on inorganic CsPbI2Br light absorberMaterials Today Energy
-
Zheng Liang, Huifen Xu, Yong Zhang, Guozhen Liu, Shenglong Chu, Yuli Tao, Xiaoxiao Xu, Shendong Xu, Liying Zhang, Xiaojing Chen, Baomin Xu, Zhengguo Xiao, Xu Pan, Jiajiu Ye (2022)
A Selective Targeting Anchor Strategy Affords Efficient and Stable Ideal‐Bandgap Perovskite Solar CellsAdvanced Materials, 34
-
Horváth O. (1998)
95J. Photochem. Photobiol., A, 114
-
Jianghu Liang, Zhanfei Zhang, Ying Huang, Qingzong Xue, Yiting Zheng, Xueyun Wu, Congcong Tian, Yi Zhang, Yimeng Wang, Zhenhua Chen, Chun‐Chao Chen (2022)
Volatile 2D Ruddlesden‐Popper Perovskite: A Gift for α‐Formamidinium Lead Triiodide Solar CellsAdvanced Functional Materials, 32
-
Luis Lanzetta, Thomas Webb, N. Zibouche, Xinxing Liang, D. Ding, G. Min, Robert Westbrook, Benedetta Gaggio, Thomas Macdonald, M. Islam, S. Haque (2021)
Degradation mechanism of hybrid tin-based perovskite solar cells and the critical role of tin (IV) iodideNature Communications, 12
-
Tong J. (2022)
642Nat. Energy, 7
-
Li H. (2021)
18724ACS Appl. Mater. Interfaces, 13
-
Zhou Z. (2022)
49886ACS Appl. Mater. Interfaces, 14
-
Yoon S. J. (2016)
1368J. Phys. Chem. Lett., 7
-
Ying Huang, Jianghu Liang, Zhanfei Zhang, Yiting Zheng, Xueyun Wu, Congcong Tian, Zhuang Zhou, Jianli Wang, Yajuan Yang, Anxin Sun, Yuan Liu, Chen Tang, Zhenhua Chen, Chun‐Chao Chen (2022)
Low‐Temperature Phase‐Transition for Compositional‐Pure α‐FAPbI3 Solar Cells with Low Residual‐Stress and High Crystal‐OrientationSmall Methods, 6
-
Lanzetta L. (2021)
2853Nat. Commun., 12
-
Zheng Y. (2022)
2200431Adv. Funct. Mater., 32
-
Jianli Wang, Zhanfei Zhang, Jianghu Liang, Yiting Zheng, Xueyun Wu, Congcong Tian, Ying Huang, Zhuang Zhou, Yajuan Yang, Anxin Sun, Zhenhua Chen, Chun‐Chao Chen (2022)
Bottom-Up Templated and Oriented Crystallization for Inverted Triple-Cation Perovskite Solar Cells with Stabilized Nickel-Oxide Interface.Small
-
Lin R. (2019)
864Nat. Energy, 4
-
Huang Y. (2022)
2200933Small Methods, 6
-
Hu S. (2022)
2096Energy Environ. Sci., 15
-
Kapil G. (2021)
2101069Adv. Energy Mater., 11
-
Yeonghun Yun, Devthade Vidyasagar, Minho Lee, Oh Gong, Jina Jung, H. Jung, Dong Kim, Sangwook Lee (2021)
Intermediate Phase‐Free Process for Methylammonium Lead Iodide Thin Film for High‐Efficiency Perovskite Solar CellsAdvanced Science, 8
-
J. Werner, Taylor Moot, Tyler Gossett, Isaac Gould, Axel Palmstrom, Eli Wolf, Caleb Boyd, M. Hest, J. Luther, J. Berry, M. McGehee (2020)
Improving Low-Bandgap Tin–Lead Perovskite Solar Cells via Contact Engineering and Gas Quench ProcessingACS energy letters, 5
-
Wu P. (2022)
2202948Adv. Energy Mater., 12
-
G. Kapil, T. Bessho, Takatoshi Maekawa, A. Baranwal, Yaohong Zhang, M. Kamarudin, D. Hirotani, Q. Shen, H. Segawa, S. Hayase (2021)
Tin‐Lead Perovskite Fabricated via Ethylenediamine Interlayer Guides to the Solar Cell Efficiency of 21.74%Advanced Energy Materials, 11
-
Tai Q. (2019)
806Angew. Chem., Int. Ed., 58
-
Kyu‐Woong Yeom, Do‐Kyoung Lee, N. Park (2022)
Hard and Soft Acid and Base (HSAB) Engineering for Efficient and Stable Sn‐Pb Perovskite Solar CellsAdvanced Energy Materials, 12
-
Min H. (2021)
444Nature, 598
-
Zhang S. (2018)
125Mater. Today Energy, 8
-
Kim E. H. (2021)
9691J. Phys. Chem. Lett., 12
-
Yiting Zheng, Xueyun Wu, Jianghu Liang, Zhanfei Zhang, Jinkun Jiang, Jianli Wang, Ying Huang, Congcong Tian, Luyao Wang, Zhenhua Chen, Chun‐Chao Chen (2022)
Downward Homogenized Crystallization for Inverted Wide‐Bandgap Mixed‐Halide Perovskite Solar Cells with 21% Efficiency and Suppressed Photo‐Induced Halide SegregationAdvanced Functional Materials, 32
-
Qidong Tai, Xuyun Guo, Guanqi Tang, Peng You, T. Ng, Dong Shen, Jiupeng Cao, Chun-Ki Liu, Naixiang Wang, Ye Zhu, Chun‐Sing Lee, Feng Yan (2018)
Antioxidant Grain Passivation for Air-Stable Tin-Based Perovskite Solar Cells.Angewandte Chemie, 58 3
-
Werner J. (2020)
1215ACS Energy Lett., 5
-
Zhengtao Xu, D. Mitzi (2003)
SnI42--Based Hybrid Perovskites Templated by Multiple Organic Cations: Combining Organic Functionalities through Noncovalent InteractionsChemistry of Materials, 15
-
Energy Mater -
Rong Y. (2016)
12892Nanoscale, 8
-
Seog Yoon, Kevin Stamplecoskie, P. Kamat (2016)
How Lead Halide Complex Chemistry Dictates the Composition of Mixed Halide Perovskites.The journal of physical chemistry letters, 7 7
-
Renxing Lin, Jian Xu, Mingyang Wei, Yurui Wang, Zhengyuan Qin, Zhou Liu, Jinlong Wu, K. Xiao, Bin Chen, So Park, Gang Chen, H. Atapattu, K. Graham, Jun Xu, Jia Zhu, Ludong Li, Chunfeng Zhang, E. Sargent, H. Tan (2022)
All-perovskite tandem solar cells with improved grain surface passivationNature, 603
-
Liang J. (2022)
2207177Adv. Funct. Mater., 32
-
Zhang Z. (2021)
17830J. Mater. Chem. A, 9
-
Saidaminov M. I. (2020)
1153ACS Energy Lett., 5
-
Kira Gardner, J. Tait, T. Merckx, W. Qiu, U. Paetzold, L. Kootstra, M. Jaysankar, R. Gehlhaar, D. Cheyns, P. Heremans, J. Poortmans (2016)
Nonhazardous Solvent Systems for Processing Perovskite PhotovoltaicsAdvanced Energy Materials, 6
-
Yin M. (2016)
8548J. Mater. Chem. A, 4
-
M. Jošt, Lukas Kegelmann, L. Korte, S. Albrecht (2020)
Monolithic Perovskite Tandem Solar Cells: A Review of the Present Status and Advanced Characterization Methods Toward 30% EfficiencyAdvanced Energy Materials, 10
-
Stamplecoskie K. G. (2015)
208Energy Environ. Sci., 8
-
Liang Z. (2022)
2110241Adv. Mater., 34
-
Yun Y. (2021)
2102492Adv. Sci., 8
-
Lin R. (2022)
73Nature, 603
-
Benesi H. A. (1949)
2703J. Am. Chem. Soc., 71
-
J. Hamill, J. Schwartz, Y. Loo (2018)
Influence of Solvent Coordination on Hybrid Organic–Inorganic Perovskite FormationACS energy letters, 3
-
H. Benesi, J. Hildebrand (1949)
A Spectrophotometric Investigation of the Interaction of Iodine with Aromatic HydrocarbonsJournal of the American Chemical Society, 71
- Publisher
- Wiley
- Copyright
- © 2023 Wiley‐VCH GmbH
- ISSN
- 1614-6832
- eISSN
- 1614-6840
- DOI
- 10.1002/aenm.202300181
- Publisher site
- See Article on Publisher Site
Abstract
Harmful Sn(IV) vacancies and uncontrolled fast crystallization commonly occur in tin–lead alloyed perovskite films. The typical dimethyl sulfoxide (DMSO) processing solvent is suggested to be the primary source of problems. Here, a DMSO‐free solvent strategy is demonstrated to obtain high‐performance Cs0.25FA0.75Pb0.5Sn0.5I3 solar cells. A rational solvent selection process via Hansen solubility parameters and Gutmann's donor number shows that N,N′‐dimethylpropyleneurea (DMPU) has a strong coordinate ability to form complete complexation with organic (formamidinium iodide) and inorganic (CsI, PbI2, and SnI2) components. This treatment suppresses the iodoplumbate (PbIn2‐n) or iodostannate (SnIn2‐n) preformed in precursor solution, thereby promoting pure intermediate complexes and retarding crystallization, realizing enlarged grain size, and improved film crystallinity. Additionally, it is demonstrated that DMPU‐based solvent system can further inhibit the oxidation of Sn(II) and reduced Sn(IV) content by nearly 75% due to its superior thermal and chemical stability. This DMSO‐free strategy generates a record efficiency of 22.41%, with a Voc of 0.88 V and a FF of 82.72% for the MA‐free Sn–Pb alloyed device. The unencapsulated devices display much‐improved humidity stability at 30 ± 5% relative humidity in air for 240 h, impressive thermal stability at 85 °C for 500 h, and promote continuous operation stability at maximum power point for 150 h.
Journal
Advanced Energy Materials – Wiley
Published: May 1, 2023
Keywords: DMSO; intermediate phase; light stability; MA‐free tin‐lead alloyed perovskites; tin oxidation; thermal stability