Dual Liquid Rubber Matrix Based Highly Efficient and Mechanically Robust Layer-by-Layer Organic Solar Cells

Yuchen Liao , Huimin Xiang , Tianyu Hu , Aziz Saparbaev , Xufan Zheng , Ming Wan , Jingnan Wu , Yating Xie , Shiqi Hu , Qi Xiao , Biao Xiao , Ergang Wang , Xunchang Wang , Renqiang Yang

SusMat ›› 2025, Vol. 5 ›› Issue (2) : e70005

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SusMat ›› 2025, Vol. 5 ›› Issue (2) : e70005 DOI: 10.1002/sus2.70005
RESEARCH ARTICLE

Dual Liquid Rubber Matrix Based Highly Efficient and Mechanically Robust Layer-by-Layer Organic Solar Cells

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Abstract

Developing organic solar cells (OSCs) simultaneously possessing high efficiency and robust mechanical properties is one of crucial tasks to ensure their operational reliability and applicability for emerging wearable devices. However, enhancing their mechanical properties without compromising the electrical properties of high-performance active materials remains a challenge. This work presents a method that overcomes this limitation by embedding a dual liquid rubber (DLR) matrix consisting of tetra-fluorophenyl azide and penta-fluorophenyl end-capped polybutadienes, PFFA and PFF, into layer-by-layer (LBL) films, which enables by a finely controlled film morphology built on strong noncovalent interactions and azide cross-linking chemistry. The resulting LBL film demonstrates a significantly improved stretchability and reduced stiffness of the active layer, with a crack initiation strain that is approximately eight times higher than that of pristine film. The potential of the DLR strategy is demonstrated in PM6:L8-BO flexible solar cells with a power conversion efficiency of 17.7%, which is among the highest efficiencies for flexible OSCs to date. More importantly, the DLR strategy also enables significant bending durability of flexible LBL OSCs that retain 84.2% of their initial performance after 5000 bending cycles. This design concept offers a new strategy for achieving highly efficient and stretchable LBL OSCs.

Keywords

cross-linking / flexible organic solar cell / liquid rubber matrix / robust mechanical

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Yuchen Liao, Huimin Xiang, Tianyu Hu, Aziz Saparbaev, Xufan Zheng, Ming Wan, Jingnan Wu, Yating Xie, Shiqi Hu, Qi Xiao, Biao Xiao, Ergang Wang, Xunchang Wang, Renqiang Yang. Dual Liquid Rubber Matrix Based Highly Efficient and Mechanically Robust Layer-by-Layer Organic Solar Cells. SusMat, 2025, 5(2): e70005 DOI:10.1002/sus2.70005

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References

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

J. S. Park, G. U. Kim, S. Lee, et al., “Material Design and Device Fabrication Strategies for Stretchable Organic Solar Cells,” Advanced Materials 34, no. 31 (2022): 2201623.
[2]

J. Yao, Q. Chen, C. Zhang, Z. Zhang, and Y. Li, “Perylene-Diimide-Based Cathode Interlayer Materials for High Performance Organic Solar Cells,” SusMat 2, no. 3 (2022): 243-263.
[3]

S. Chu and A. Majumdar, “Opportunities and Challenges for a Sustainable Energy Future,” Nature 488, no. 7411 (2012): 294-303.
[4]

Q. He, P. Ufimkin, F. Aniés, et al., “Molecular Engineering of Y-Series Acceptors for Nonfullerene Organic Solar Cells,” SusMat 2, no. 5 (2022): 591-606.
[5]

T. Kim, J.-H. Kim, T. E. Kang, et al., “Flexible, Highly Efficient All-Polymer Solar Cells,” Nature Communications 6, no. 1 (2015): 8547.
[6]

D. Zhang, Y. Wu, C. Yan, et al., “Simultaneously Improving Stretchability and Efficiency of Flexible Organic Solar Cells by Incorporating a Copolymer Interlayer in Active Layer,” Advanced Functional Materials 8, no. 46 (2024): 2407681.
[7]

Z. Chen, J. Zhu, D. Yang, et al., “Isomerization Strategy on a Non-Fullerene Guest Acceptor for Stable Organic Solar Cells With Over 19% Efficiency,” Energy & Environmental Science 16, no. 7 (2023): 3119-3127.
[8]

Q. Zhu, J. Xue, H. Zhao, et al., “Highly Efficient Organic Solar Cells With Superior Deformability Enabled by Diluting the Small Molecule Acceptor Content,” Journal of Materials Chemistry A 10, no. 15 (2022): 8293-8302.
[9]

D. J. Lipomi, B. C. K. Tee, M. Vosgueritchian, and Z. Bao, “Stretchable Organic Solar Cells,” Advanced Materials 15, no. 15 (2011): 1771-1775.
[10]

Z. Wang, D. Zhang, M. Xu, et al., “Intrinsically Stretchable Organic Solar Cells With Simultaneously Improved Mechanical Robustness and Morphological Stability Enabled by a Universal Crosslinking Strategy,” Small 18, no. 26 (2022): 2201589.
[11]

J. Qiu, Q. Zhou, M. Yu, et al., “Modulating CsPbl,” SusMat 3, no. 6 (2023): 894-908.
[12]

A. X. Chen, A. T. Kleinschmidt, K. Choudhary, and D. J. Lipomi, “Beyond Stretchability:Strength, Toughness, and Elastic Range in Semiconducting Polymers,” Chemistry of Materials 32, no. 18 (2020): 7582-7601.
[13]

J. W. Lee, H. G. Lee, E. S. Oh, et al., “Rigid- and Soft-Block-Copolymerized Conjugated Polymers Enable High-Performance Intrinsically Stretchable Organic Solar Cells,” Joule 8, no. 1 (2024): 204-223.
[14]

L. Tian, C. Liu, and F. Huang, “Recent Progress in Side Chain Engineering of Y-Series Non-Fullerene Molecule and Polymer Acceptors,” Science China Chemistry 67, no. 3 (2024): 788-805.
[15]

Q. Fan, Q. Xiao, H. Zhang, et al., “Highly Efficient and Stable ITO-Free Organic Solar Cells Based on Squaraine N-Doped Quaternary Bulk Heterojunction,” Advanced Materials 36, no. 3 (2024): 2307920.
[16]

X. Sun, X. Ding, F. Wang, et al., “Binary Organic Solar Cells With >19.6% Efficiency:The Significance of Self-Assembled Monolayer Modification,” ACS Energy Letters 9 (2024): 4209-4217.
[17]

Y. J. A. Tamai, “Charge Generation in Organic Solar Cells:Journey Toward 20% Power Conversion Efficiency:Special Issue:Emerging Investigators,” Aggregate 3, no. 6 (2022): e280.
[18]

D. Zhang, Y. Ji, Y. Cheng, et al., “High-Efficiency Ultrathin Flexible Organic Solar Cells With a Bilayer Hole Transport Layer,” Journal of Materials Chemistry A 12, no. 25 (2024): 15099-15105.
[19]

J. Fu, Q. Yang, P. Huang, et al., “Rational Molecular and Device Design Enables Organic Solar Cells Approaching 20% Efficiency,” Nature Communications 15, no. 1 (2024): 1830.
[20]

W. Feng, T. Chen, Y. Li, et al., “Binary All-Polymer Solar Cells With a Perhalogenated-Thiophene-Based Solid Additive Surpass 18 % Efficiency,” Angewandte Chemie International Edition 136, no. 9 (2024): e202316698.
[21]

Q. Wan, S. Seo, S. W. Lee, et al., “High-Performance Intrinsically Stretchable Polymer Solar Cell With Record Efficiency and Stretchability Enabled by Thymine-Functionalized Terpolymer,” Journal of the American Chemical Society 145, no. 22 (2023): 11914-11920.
[22]

X. Chen, G. Xu, G. Zeng, et al., “Realizing Ultrahigh Mechanical Flexibility and >15% Efficiency of Flexible Organic Solar Cells via a “Welding” Flexible Transparent Electrode,” Advanced Materials 32, no. 14 (2020): 1908478.
[23]

W. Xia, B. Zhou, L. Wang, et al., “Insulating Polymer Mediated Stability and Photovoltaic Performance of Organic Solar Cells:Influence of Molecular Weight,” Advanced Functional Materials 8, no. 48 (2024): 2408340.
[24]

A. Shafe, H. M. Schrickx, K. Ding, and H. Ade, “Rubber-Toughened Organic Solar Cells:Miscibility-Morphology-Performance Relations,” ACS Energy Letters 8, no. 9 (2023): 3720-3726.
[25]

S. Li, M. Gao, K. Zhou, et al., “Achieving Record-High Stretchability and Mechanical Stability in Organic Photovoltaic Blends With a Dilute-Absorber Strategy,” Advanced Materials 36, no. 8 (2024): 2307278.
[26]

Y. Zheng, S. Zhang, J. B. H. Tok, and Z. Bao, “Molecular Design of Stretchable Polymer Semiconductors:Current Progress and Future Directions,” Journal of the American Chemical Society 144, no. 11 (2022): 4699-4715.
[27]

S. Seo, J. W. Lee, D. J. Kim, et al., “Poly (dimethylsiloxane)-Block-PM6 Polymer Donors for High-Performance and Mechanically Robust Polymer Solar Cells,” Advanced Materials 35, no. 24 (2023): 2300230.
[28]

Y. Pan, C. Yan, X. Zhao, et al., “11.39% Efficiency Cu2ZnSn (S, Se)4 Solar Cells From Scrap Brass,” SusMat 2, no. 2 (2022): 206-211.
[29]

J.-J. Han, C.-S. Wei, A. Lu, et al., “Visualizing Filler Network to Reveal Structural Mechanisms on Energy Dissipation of Mullins Effect in Silicone Rubber,” Polymer 301 (2024): 127044.
[30]

Y. Zhao, X. Zhao, M. Roders, et al., “Melt-Processing of Complementary Semiconducting Polymer Blends for High Performance Organic Transistors,” Advanced Materials 29, no. 6 (2016): 1605056.
[31]

S. E. Root, S. Savagatrup, A. D. Printz, D. Rodriquez, and D. J. Lipomi, “Mechanical Properties of Organic Semiconductors for Stretchable, Highly Flexible, and Mechanically Robust Electronics,” Chemical Reviews 117, no. 9 (2017): 6467-6499.
[32]

G.-J. N. Wang, Y. Zheng, S. Zhang, et al., “Tuning the Cross-Linker Crystallinity of a Stretchable Polymer Semiconductor,” Chemistry of Materials 31, no. 17 (2018): 6465-6475.
[33]

J. W. Lee, T. H. Q. Nguyen, E. S. Oh, et al., “Establishing Co-Continuous Network of Conjugated Polymers and Elastomers for High-Performance Polymer Solar Cells With Extreme Stretchability,” Advanced Energy Materials 14, no. 26 (2024): 2401191.
[34]

S. Savagatrup, X. Zhao, E. Chan, J. Mei, and D. J. Lipomi, “Effect of Broken Conjugation on the Stretchability of Semiconducting Polymers,” Macromolecular Rapid Communications 37, no. 19 (2016): 1623-1628.
[35]

J. Y. Oh, S. Rondeau-Gagné, Y.-C. Chiu, et al., “Intrinsically Stretchable and Healable Semiconducting Polymer for Organic Transistors,” Nature 539, no. 7629 (2016): 411-415.
[36]

M. Q. Zhang, “Dynamic Bonds in Polymers,” Journal of Polymer Science 62, no. 5 (2024): 785-786.
[37]

K. Yu, A. Xin, and Q. Wang, “Mechanics of Self-Healing Polymer Networks Crosslinked by Dynamic Bonds,” Journal of the Mechanics and Physics of Solids 121 (2018): 409-431.
[38]

N. Y. Kwon, S. H. Park, S. Cho, et al., “Polymer Solar Cells Made With Photocrosslinkable Conjugated Donor-Acceptor Block Copolymers:Improvement in the Thermal Stability and Morphology With a Single-Component Active Layer,” Polymer Chemistry 13, no. 22 (2022): 3335-3342.
[39]

Y. He, N. Li, T. Heumüller, et al., “Industrial Viability of Single-Component Organic Solar Cells,” Joule 6, no. 6 (2022): 1160-1171.
[40]

E. Dauzon, X. Sallenave, C. Plesse, et al., “Versatile Methods for Improving the Mechanical Properties of Fullerene and Non-Fullerene Bulk Heterojunction Layers to Enable Stretchable Organic Solar Cells,” Journal of Materials Chemistry C 10, no. 9 (2022): 3375-3386.
[41]

J. D. Cho, S. Jung, J.-I. Kim, and C. H. Choi, “Improvement of Performance for Flexible Film Dosimeter by Incorporating Additive Agents,” Physics in Medicine and Biology 69, no. 10 (2024): 105006.
[42]

J. Han, F. Bao, X. Wang, et al., “Identifying Tunneling Effects of Poly(aryl Ether) Matrices and Boosting the Efficiency, Stability, and Stretchability of Organic Solar Cells,” Cell Reports Physical Science 2, no. 5 (2021): 100408.
[43]

J. Xu, S. Wang, G.-J. N. Wang, et al., “Highly Stretchable Polymer Semiconductor Films Through the Nanoconfinement Effect,” Science 355, no. 6320 (2017): 59-64.
[44]

J. Wang, C. Han, J. Han, et al., “Synergetic Strategy for Highly Efficient and Super Flexible Thick-Film Organic Solar Cells,” Advanced Energy Materials 12, no. 31 (2022): 2201614.
[45]

B. Park, H. Kang, Y. H. Ha, et al., “Direct Observation of Confinement Effects of Semiconducting Polymers in Polymer Blend Electronic Systems,” Advancement of Science 8, no. 14 (2021): 2100332.
[46]

I. Angunawela, M. M. Nahid, M. Ghasemi, et al., “The Critical Role of Materials' Interaction in Realizing Organic Field-Effect Transistors via High-Dilution Blending With Insulating Polymers,” ACS Applied Materials & Interfaces 12, no. 23 (2020): 26239-26249.
[47]

Q. An, F. Zhang, J. Zhang, et al., “Versatile Ternary Organic Solar Cells: A Critical Review,” Energy & Environmental Science 9, no. 2 (2016): 281-322.
[48]

N. Gasparini, A. Salleo, I. McCulloch, and D. Baran, “The Role of the Third Component in Ternary Organic Solar Cells,” Nature Reviews Materials 4, no. 4 (2019): 229-242.
[49]

L. Lu, M. A. Kelly, W. You, and L. Yu, “Status and Prospects for Ternary Organic Photovoltaics,” Nature Photonics 9, no. 8 (2015): 491-500.
[50]

Z. Peng, K. Xian, Y. Cui, et al., “Thermoplastic Elastomer Tunes Phase Structure and Promotes Stretchability of High-Efficiency Organic Solar Cells,” Advanced Materials 33, no. 49 (2021): 2106732.
[51]

D. Sarkar, M. Dhar, A. Das, et al., “Covalent Crosslinking Chemistry for Controlled Modulation of Nanometric Roughness and Surface Free Energy,” Chemical Science 15, no. 13 (2024): 4938-4951.
[52]

H. Tan, L. Zhang, X. Ma, L. Sun, D. Yu, and Z. You, “Adaptable Covalently Cross-Linked Fibers,” Nature Communications 14, no. 1 (2023): 2218.
[53]

K. Jiang, G. Zhang, G. Yang, et al., “Multiple Cases of Efficient Nonfullerene Ternary Organic Solar Cells Enabled by an Effective Morphology Control Method,” Advanced Energy Materials 8, no. 9 (2018): 1701370.
[54]

D. J. Lundberg, C. M. Brown, E. O. Bobylev, et al., “Nested Non-Covalent Interactions Expand the Functions of Supramolecular Polymer Networks,” Nature Communications 15, no. 1 (2024): 3951.
[55]

C. Guan, C. Xiao, X. Liu, et al., “Non-Covalent Interactions Between Polyvinyl Chloride and Conjugated Polymers Enable Excellent Mechanical Properties and High Stability in Organic Solar Cells,” Angewandte Chemie International Edition 135, no. 44 (2023): e202312357.
[56]

L. A. Galuska, M. U. Ocheje, Z. C. Ahmad, S. Rondeau-Gagné, and X. Gu, “Elucidating the Role of Hydrogen Bonds for Improved Mechanical Properties in a High-Performance Semiconducting Polymer,” Chemistry of Materials 34, no. 5 (2022): 2259-2267.
[57]

S. Kamimura, M. Saito, Y. Teshima, et al., “Manipulating the Functionality and Structures of π-Conjugated Polymers Utilizing Intramolecular Noncovalent Interactions Towards Efficient Organic Photovoltaics,” Chemical Science 15, no. 17 (2024): 6349-6362.
[58]

Q. Fan, U. A. Méndez-Romero, X. Guo, et al., “Fluorinated Photovoltaic Materials for High-Performance Organic Solar Cells,” Chemistry—An Asian Journal 14, no. 18 (2019): 3085-3095.
[59]

G. V. Janjić, S. T. Jelić, N. P. Trišović, D. M. Popović, I. Đorđević, and M. Milčić, “New Theoretical Insight Into Fluorination and Fluorine-Fluorine Interactions as a Driving Force in Crystal Structures,” Crystal Growth & Design 20, no. 5 (2020): 2943-2951.
[60]

D. W. Y. Teo, Z. Jamal, Q.-J. Seah, R.-Q. Png, and L.-L. Chua, “General Bis(fluorophenyl Azide) Photo-Crosslinkers for Conjugated and Non-Conjugated Polyelectrolytes,” Journal of Materials Chemistry C 8, no. 1 (2020): 253-261.
[61]

K. E. Hung, Y. S. Lin, Y. J. Xue, et al., “Non-Volatile Perfluorophenyl-Based Additive for Enhanced Efficiency and Thermal Stability of Nonfullerene Organic Solar Cells via Supramolecular Fluorinated Interactions,” Advanced Energy Materials 12, no. 12 (2022): 2103702.
[62]

Y. Zheng, Z. Yu, S. Zhang, et al., “A Molecular Design Approach Towards Elastic and Multifunctional Polymer Electronics,” Nature Communications 12, no. 1 (2021): 5701.
[63]

R.-Q. Png, P.-J. Chia, J.-C. Tang, et al., “High-Performance Polymer Semiconducting Heterostructure Devices by Nitrene-Mediated Photocrosslinking of Alkyl Side Chains,” Nature Materials 9, no. 2 (2010): 152-158.
[64]

S. H. Kim, S. Chung, M. Kim, et al., “Designing a Length-Modulated Azide Photocrosslinker to Improve the Stretchability of Semiconducting Polymers,” Advanced Functional Materials 33, no. 23 (2023): 2212127.
[65]

J. Kim, G. Zhang, M. Shi, and Z. Suo, “Fracture, Fatigue, and Friction of Polymers in Which Entanglements Greatly Outnumber Cross-Links,” Science 374, no. 6564 (2021): 212-216.
[66]

H. Huang, L. Yang, A. Facchetti, and T. J. Marks, “Organic and Polymeric Semiconductors Enhanced by Noncovalent Conformational Locks,” Chemical Reviews 117, no. 15 (2017): 10291-10318.
[67]

M. Zhang, L. Zhu, T. Hao, et al., “High-Efficiency Organic Photovoltaics Using Eutectic Acceptor Fibrils to Achieve Current Amplification,” Advanced Materials 33, no. 18 (2021): 2007177.
[68]

C. Li, J. Zhou, J. Song, et al., “Non-Fullerene Acceptors With Branched Side Chains and Improved Molecular Packing to Exceed 18% Efficiency in Organic Solar Cells,” Nature Energy 6, no. 6 (2021): 605-613.
[69]

J. Y. Chung, A. J. Nolte, and C. M. Stafford, “Surface Wrinkling: A Versatile Platform for Measuring Thin-Film Properties,” Advanced Materials 23, no. 3 (2011): 349-368.
[70]

D. E. Martínez-Tong, A. Najar, M. Soccio, et al., “Quantitative Mapping of Mechanical Properties in Polylactic Acid/Natural Rubber/Organoclay Bionanocomposites as Revealed by Nanoindentation With Atomic Force Microscopy,” Composites Science and Technology 104 (2014): 34-39.
[71]

D. Rodriquez, J.-H. Kim, S. E. Root, et al., “Comparison of Methods for Determining the Mechanical Properties of Semiconducting Polymer Films for Stretchable Electronics,” ACS Applied Materials & Interfaces 9, no. 10 (2017): 8855-8862.
[72]

S. Kim, J.-H. Kim, J.-G. Oh, et al., “Mechanical Behavior of Free-Standing Fuel Cell Electrodes on Water Surface,” ACS Applied Materials & Interfaces 8, no. 24 (2016): 15391-15398.
[73]

M. Saito, T. Fukuhara, S. Kamimura, et al., “Impact of Noncovalent Sulfur-Fluorine Interaction Position on Properties, Structures, and Photovoltaic Performance in Naphthobisthiadiazole-Based Semiconducting Polymers,” Advanced Energy Materials 10, no. 7 (2020): 1903278.
[74]

M. Schock and S. J. M. Bräse, “Reactive & Efficient:Organic Azides as Cross-Linkers in Material Sciences,” Molecules 25, no. 4 (2020): 1009.
[75]

Z. Peng, K. Xian, J. Liu, et al., “Unraveling the Stretch-Induced Microstructural Evolution and Morphology-Stretchability Relationships of High-Performance Ternary Organic Photovoltaic Blends,” Advanced Materials 35, no. 3 (2023): 2207884.
[76]

Y. Cai, Q. Li, G. Lu, et al., “Vertically Optimized Phase Separation With Improved Exciton Diffusion Enables Efficient Organic Solar Cells With Thick Active Layers,” Nature Communications 13, no. 1 (2022): 2369.
[77]

Z. Lian, Q. Yan, T. Gao, et al., “Perovskite CH3NH3PbI3 (Cl) Single Crystals:Rapid Solution Growth, Unparalleled Crystalline Quality, and Low Trap Density Toward 108 cm−3,” Journal of the American Chemical Society 138, no. 30 (2016): 9409-9412.
[78]

R. Yu, G. Wu, Y. Cui, et al., “Multi-Functional Solid Additive Induced Favorable Vertical Phase Separation and Ordered Molecular Packing for Highly Efficient Layer-by-Layer Organic Solar Cells,” Small 17, no. 44 (2021): 2103497.
[79]

F. Sun, X. Wang, M. Wan, et al., “High Miscibility-Induced Reduction of Trap Density in All-Polymer Solar Cells Using Hybrid Cyclohexyl-Hexyl Side Chains,” Advanced Functional Materials 33, no. 40 (2023): 2306791.
[80]

M. Haris, Z. Ullah, S. Lee, et al., “Amplifying High-Performance Organic Solar Cells Through Differencing Interactions of Solid Additive With Donor/Acceptor Materials Processed From Non-Halogenated Solvent,” Advanced Energy Materials 12, no. 35 (2024): 2401597.
[81]

Y. Ran, C. Liang, Z. Xu, et al., “Developing Efficient Benzene Additives for 19.43% Efficiency of Organic Solar Cells by Crossbreeding Effect of Fluorination and Bromination,” Advanced Functional Materials 34, no. 8 (2024): 2311512.
[82]

X. Wang, J. Wang, P. Wang, et al., “Embedded Host/Guest Alloy Aggregations Enable High-Performance Ternary Organic Photovoltaics,” Advanced Materials 35, no. 51 (2023): 2305652.
[83]

Q. Ye, Z. Chen, D. Yang, et al., “Ductile Oligomeric Acceptor-Modified Flexible Organic Solar Cells Show Excellent Mechanical Robustness and Near 18% Efficiency,” Advanced Materials 35, no. 44 (2023): 2305562.

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