Synergistic Chemical and Physical Encapsulation Strategies Enable Highly Stable and Lead Leakage-Suppressed Perovskite Solar Cells

Yumeng Xu , Qingrui Wang , Zhenhua Lin , Siyu Zhang , Xing Guo , Zhaosheng Hu , Juanxiu Xiao , Yue Hao , Liming Ding , Jingjing Chang

Interdisciplinary Materials ›› 2025, Vol. 4 ›› Issue (4) : 599 -609.

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Interdisciplinary Materials ›› 2025, Vol. 4 ›› Issue (4) :599 -609. DOI: 10.1002/idm2.12255
RESEARCH ARTICLE

Synergistic Chemical and Physical Encapsulation Strategies Enable Highly Stable and Lead Leakage-Suppressed Perovskite Solar Cells

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Abstract

Although outstanding power conversion efficiency has been achieved in perovskite solar cells (PSCs), poor stability and lead (Pb) toxicity are still the key challenges limiting the commercial application of PSCs. Herein, we adopted both chemical encapsulation and physical encapsulation to address these problems. Via strong chemical interaction between dibutyl phthalate (DBP) and perovskite, the chemical encapsulation strategy results in higher perovskite film quality with reduced trap density, and the device efficiency enhances from 22.07% to 24.36%. Physical encapsulation polymer with high film robustness and self-healing properties could effectively isolate external risks and restore protection after physical damage. Furthermore, both chemical and physical encapsulation materials could trap Pb ions leaking from the perovskite materials by forming coordination interactions. We simulated realistic scenarios in which PSCs encapsulated by different methods suffered water immersion and mechanical damage, and quantitatively measured Pb leakage rates under different conditions. Higher device stability and greater Pb leakage reduction were achieved, confirming the excellent encapsulation effect of the synergy of chemical and physical encapsulation. This study provides an effective strategy to realize safe and environmentally friendly PSCs to promote their commercialization.

Keywords

chemical encapsulation / lead leakage / perovskite solar cells / physical encapsulation

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Yumeng Xu, Qingrui Wang, Zhenhua Lin, Siyu Zhang, Xing Guo, Zhaosheng Hu, Juanxiu Xiao, Yue Hao, Liming Ding, Jingjing Chang. Synergistic Chemical and Physical Encapsulation Strategies Enable Highly Stable and Lead Leakage-Suppressed Perovskite Solar Cells. Interdisciplinary Materials, 2025, 4(4): 599-609 DOI:10.1002/idm2.12255

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

A. Kojima, K. Teshima, Y. Shirai, and T. Miyasaka, “Organometal Halide Perovskites as Visible-Light Sensitizers for Photovoltaic Cells,” Journal of the American Chemical Society 131 (2009): 6050–6051.
[2]

“Best Research-Cell Efficiencies,” 2025, https://www.nrel.gov/pv/cell-efficiency.html.
[3]

S. Yang, S. Chen, E. Mosconi, et al., “Stabilizing Halide Perovskite Surfaces for Solar Cell Operation With Wide-Bandgap Lead Oxysalts,” Science 365 (2019): 473–478.
[4]

Y. Ma, Y. Cheng, X. Xu, et al., “Suppressing Ion Migration Across Perovskite Grain Boundaries by Polymer Additives,” Advanced Functional Materials 31 (2021): 2006802.
[5]

Y. Ge, F. Ye, M. Xiao, et al., “Internal Encapsulation for Lead Halide Perovskite Films for Efficient and Very Stable Solar Cells,” Advanced Energy Materials 12 (2022): 2200361.
[6]

X. Meng, X. Hu, Y. Zhang, et al., “A Biomimetic Self - Shield Interface for Flexible Perovskite Solar Cells With Negligible Lead Leakage,” Advanced Functional Materials 31 (2021): 2106460.
[7]

Q. Wang, Z. Lin, Y. Xu, et al., “Chelating Resin Encapsulation for Reduced Pb Leakage in Perovskite Solar Cells,” EcoMat 5 (2023): e12400.
[8]

T. Zhang, F. Qian, H. Chen, et al., “Critical Role of Post-Treatment Induced Surface Reconstruction for High Performance Inorganic Tin-Lead Perovskite Solar Cells,” Chemical Engineering Journal 479 (2024): 147554.
[9]

T. Zhang, F. Wang, H. Chen, et al., “Synchronized B-Site Alloying for High - Efficiency Inorganic Tin - Lead Perovskite Solar Cells,” Applied Physics Reviews 10 (2023): 41417.
[10]

J. Chen, J. Luo, E. Hou, et al., “Efficient Tin-Based Perovskite Solar Cells With Trans-Isomeric Fulleropyrrolidine Additives,” Nature Photonics 18 (2024): 464–470.
[11]

L. Wang, H. Bi, J. Liu, et al., “Exceeding 15% Performance With Energy Level Tuning in Tin-Based Perovskite Solar Cells,” ACS Energy Letters 9 (2024): 6238–6244.
[12]

J. Dou, Y. Bai, and Q. Chen, “Challenges of Lead Leakage in Perovskite Solar Cells,” Materials Chemistry Frontiers 6 (2022): 2779–2789.
[13]

Y. Jiang, L. Qiu, E. J. Juarez-Perez, et al., “Reduction of Lead Leakage From Damaged Lead Halide Perovskite Solar Modules Using Self-Healing Polymer-Based Encapsulation,” Nature Energy 4 (2019): 585–593.
[14]

Q. Wang, Z. Lin, J. Su, et al., “Dithiol Surface Treatment towards Improved Charge Transfer Dynamic and Reduced Lead Leakage in Lead Halide Perovskite Solar Cells,” EcoMat 4 (2022): e12185.
[15]

Q. Q. Chu, Z. Sun, D. Wang, et al., “Encapsulation: The Path to Commercialization of Stable Perovskite Solar Cells,” Matter 6 (2023): 3838–3863.
[16]

S. Emami, J. Martins, R. Madureira, et al., “Development of Hermetic Glass Frit Encapsulation for Perovskite Solar Cells,” Journal of Physics D: Applied Physics 52 (2019): 074005.
[17]

D. Xu, R. Mai, Y. Jiang, et al., “An Internal Encapsulating Layer for Efficient, Stable, Repairable and Low-Lead-Leakage Perovskite Solar Cells,” Energy & Environmental Science 15 (2022): 3891–3900.
[18]

Y. Cao, J. Feng, M. Wang, et al., “Interface Modification by Ammonium Sulfamate for High-Efficiency and Stable Perovskite Solar Cells,” Advanced Energy Materials 13 (2023): 2302103.
[19]

Z. Chen, Q. Cheng, H. Chen, et al., “Perovskite Grain-Boundary Manipulation Using Room-Temperature Dynamic Self-Healing ‘Ligaments’ for Developing Highly Stable Flexible Perovskite Solar Cells With 23.8% Efficiency,” Advanced Materials 35 (2023): 2300513.
[20]

M. Yang, T. Tian, Y. Fang, et al., “Reducing Lead Toxicity of Perovskite Solar Cells With a Built-in Supramolecular Complex,” Nature Sustainability 6 (2023): 1455–1464.
[21]

Q. Cao, T. Wang, J. Yang, et al., “Environmental - Friendly Polymer for Efficient and Stable Inverted Perovskite Solar Cells With Mitigating Lead Leakage,” Advanced Functional Materials 32 (2022): 2201036.
[22]

J. Yang, W. Sheng, X. Li, et al., “Synergistic Toughening and Self-Healing Strategy for Highly Efficient and Stable Flexible Perovskite Solar Cells,” Advanced Functional Materials 33 (2023): 2214984.
[23]

H. Zheng, X. Peng, T. Chen, et al., “Boosting Efficiency and Stability of 2D Alternating Cation Perovskite Solar Cells via Rational Surface-Modification: Marked Passivation Efficacy of Anion,” Journal of Energy Chemistry 84 (2023): 354–362.
[24]

H. Dong, G. Shen, H. Fang, et al., “Internal Encapsulation Strategy Using a Polymer Enables Efficient, Stable, and Lead-Safe Inverted Perovskite Solar Cells,” Advanced Functional Materials (2024): 2402394.
[25]

J. Liang, X. Hu, C. Wang, et al., “Origins and Influences of Metallic Lead in Perovskite Solar Cells,” Joule 6 (2022): 816–833.
[26]

D. Bi, C. Yi, J. Luo, et al., “Polymer-Templated Nucleation and Crystal Growth of Perovskite Films for Solar Cells With Efficiency Greater Than 21%,” Nature Energy 1 (2016): 16142.
[27]

F. Liu, K. Liu, S. Rafique, et al., “Highly Efficient and Stable Self-Powered Mixed Tin-Lead Perovskite Photodetector Used in Remote Wearable Health Monitoring Technology,” Advanced Science 10 (2023): 2205879.
[28]

T. Zhou, Z. Xu, R. Wang, X. Dong, Q. Fu, and Y. Liu, “ Crystal Growth Regulation of 2D/3D Perovskite Films for Solar Cells With Both High Efficiency and Stability,” Advanced Materials 34 (2022): 2200705.
[29]

M. Gao, X. Han, X. Zhan, et al., “Enhancement in Photoelectric Performance of Flexible Perovskite Solar Cells by Thermal Nanoimprint Pillar-Like Nanostructures,” Materials Letters 248 (2019): 16–19.
[30]

Y. Zhao, F. Ma, Z. Qu, et al., “Inactive (PbI2)2RbCl Stabilizes Perovskite Films for Efficient Solar Cells,” Science 377 (2022): 531–534.
[31]

Y. Yan, R. Wang, Q. Dong, et al., “Polarity and Moisture Induced Trans-Grain-Boundaries 2D/3D Coupling Structure for Flexible Perovskite Solar Cells With High Mechanical Reliability and Efficiency,” Energy & Environmental Science 15 (2022): 5168–5180.
[32]

M. Li, R. Sun, J. Chang, et al., “Orientated Crystallization of FA-Based Perovskite via Hydrogen-Bonded Polymer Network for Efficient and Stable Solar Cells,” Nature Communications 14 (2023): 573.
[33]

Y. Xu, X. Guo, Z. Lin, et al., “Perovskite Films Regulation via Hydrogen-Bonded Polymer Network for Efficient and Stable Perovskite Solar Cells,” Angewandte Chemie International Edition 62 (2023): e202306229.
[34]

Y. Zhang, R. Yu, M. Li, et al., “Amphoteric Ion Bridged Buried Interface for Efficient and Stable Inverted Perovskite Solar Cells,” Advanced Materials 36 (2024): 2310203.
[35]

Q. Chen, H. Zhou, T.-B. Song, et al., “Controllable Self-Induced Passivation of Hybrid Lead Iodide Perovskites Toward High Performance Solar Cells,” Nano Letters 14 (2014): 4158–4163.
[36]

B. Park, N. Kedem, M. Kulbak, et al., “Understanding How Excess Lead Iodide Precursor Improves Halide Perovskite Solar Cell Performance,” Nature Communications 9 (2018): 3301.
[37]

C. Wu, D. Wang, Y. Zhang, et al., “FAPbI3 Flexible Solar Cells With a Record Efficiency of 19.38% Fabricated in Air via Ligand and Additive Synergetic Process,” Advanced Functional Materials 29 (2019): 1902974.
[38]

Y. Shao, Z. Xiao, C. Bi, Y. Yuan, and J. Huang, “Origin and Elimination of Photocurrent Hysteresis by Fullerene Passivation in CH3NH3PbI3 Planar Heterojunction Solar Cells,” Nature Communications 5 (2014): 5784.
[39]

H. Zhou, Q. Chen, G. Li, et al., “Interface Engineering of Highly Efficient Perovskite Solar Cells,” Science 345 (2014): 542–546.
[40]

D. Y. Son, J. W. Lee, Y. J. Choi, et al., “Self-Formed Grain Boundary Healing Layer for Highly Efficient CH3NH3PbI3 Perovskite Solar Cells,” Nature Energy 1 (2016): 16081.
[41]

X. Guo, J. Su, Z. Lin, et al., “Synergetic Surface Charge Transfer Doping and Passivation Toward High Efficient and Stable Perovskite Solar Cells,” iScience 24 (2021): 102276.
[42]

Q. Jiang, Z. Ni, G. Xu, et al., “Interfacial Molecular Doping of Metal Halide Perovskites for Highly Efficient Solar Cells,” Advanced Materials 32 (2020): 2001581.
[43]

Z. Zhang, L. Qiao, K. Meng, R. Long, G. Chen, and P. Gao, “Rationalization of Passivation Strategies Toward High-Performance Perovskite Solar Cells,” Chemical Society Reviews 52 (2023): 163–195.
[44]

Y.-W. Jang, S. Lee, K. M. Yeom, et al., “Intact 2D/3D Halide Junction Perovskite Solar Cells via Solid-Phase in-Plane Growth,” Nature Energy 6 (2021): 63–71.
[45]

L. Zhou, J. Su, Z. Lin, et al., “Synergistic Interface Layer Optimization and Surface Passivation With Fluorocarbon Molecules Toward Efficient and Stable Inverted Planar Perovskite Solar Cells,” Research 2021 (2021): 9836752.
[46]

X. Zheng, Y. Deng, B. Chen, et al., “Dual Functions of Crystallization Control and Defect Passivation Enabled by Sulfonic Zwitterions for Stable and Efficient Perovskite Solar Cells,” Advanced Materials 30 (2018): 1803428.
[47]

N. Zhu, X. Qi, Y. Zhang, et al., “High Efficiency (18.53%) of Flexible Perovskite Solar Cells via the Insertion of Potassium Chloride Between SnO2 and CH3NH3PbI3 Layers,” ACS Applied Energy Materials 2 (2019): 3676–3682.
[48]

J. He, J. Su, Z. Lin, et al., “Enhanced Efficiency and Stability of All-Inorganic CsPbI2Br Perovskite Solar Cells by Organic and Ionic Mixed Passivation,” Advanced Science 8 (2021): 2101367.
[49]

L. Zhou, Z. Lin, Z. Ning, et al., “Highly Efficient and Stable Planar Perovskite Solar Cells With Modulated Diffusion Passivation Toward High Power Conversion Efficiency and Ultrahigh Fill Factor,” Solar RRL 3 (2019): 1900293.
[50]

W. Peng, L. Wang, B. Murali, et al., “Solution-Grown Monocrystalline Hybrid Perovskite Films for Hole-Transporter-Free Solar Cells,” Advanced Materials 28 (2016): 3383–3390.
[51]

R. Guo, D. Han, W. Chen, et al., “Degradation Mechanisms of Perovskite Solar Cells Under Vacuum and One Atmosphere of Nitrogen,” Nature Energy 6 (2021): 977–986.

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