Over 18% binary organic solar cells enabled by isomerization of non-fullerene acceptors with alkylthiophene side chains
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Siwei Luo | W. Ma | Xinxin Xia | Xinhui Lu | Heng Zhao | Jianquan Zhang | Huawei Hu | Mingao Pan | Jicheng Yi | Yuzhong Chen | Ao Shang | Chao Li | He Yan | Wei Ma
[1] Yongsheng Chen,et al. Tuning Morphology of Active Layer by using a Wide Bandgap Oligomer‐Like Donor Enables Organic Solar Cells with Over 18% Efficiency , 2022, Advanced Energy Materials.
[2] W. Ma,et al. Realizing 19.05% Efficiency Polymer Solar Cells by Progressively Improving Charge Extraction and Suppressing Charge Recombination , 2022, Advanced materials.
[3] Xiaowei Zhan,et al. Morphology Control in Organic Solar Cells , 2018 .
[4] Shinuk Cho,et al. Solid-Solvent Hybrid Additive for the Simultaneous Control of the Macro- and Micro-Morphology in Non-Fullerene-Based Organic Solar Cells , 2021, Nano Energy.
[5] F. Gao,et al. A guest-assisted molecular-organization approach for >17% efficiency organic solar cells using environmentally friendly solvents , 2021, Nature Energy.
[6] H. Ade,et al. Alkyl‐Chain Branching of Non‐Fullerene Acceptors Flanking Conjugated Side Groups toward Highly Efficient Organic Solar Cells , 2021, Advanced Energy Materials.
[7] Zhishan Bo,et al. Simple Nonfused Ring Electron Acceptors with 3D Network Packing Structure Boosting the Efficiency of Organic Solar Cells to 15.44% , 2021, Advanced Energy Materials.
[8] W. Li,et al. Enabling High Efficiency of Hydrocarbon‐Solvent Processed Organic Solar Cells through Balanced Charge Generation and Non‐Radiative Loss , 2021, Advanced Energy Materials.
[9] Liming Ding,et al. Side chain engineering on D18 polymers yields 18.74% power conversion efficiency , 2021, Journal of Semiconductors.
[10] Yongfang Li,et al. Volatilizable Solid Additive‐Assisted Treatment Enables Organic Solar Cells with Efficiency over 18.8% and Fill Factor Exceeding 80% , 2021, Advanced materials.
[11] Q. Peng,et al. 18.77% Efficiency Organic Solar Cells Promoted by Aqueous Solution Processed Cobalt(II) Acetate Hole Transporting Layer. , 2021, Angewandte Chemie.
[12] Jianhui Hou,et al. A Tandem Organic Photovoltaic Cell with 19.6% Efficiency Enabled by Light Distribution Control , 2021, Advanced materials.
[13] H. Ade,et al. A Chlorinated Donor Polymer Achieving High‐Performance Organic Solar Cells with a Wide Range of Polymer Molecular Weight , 2021, Advanced Functional Materials.
[14] H. Xia,et al. Nanographene–Osmapentalyne Complexes as a Cathode Interlayer in Organic Solar Cells Enhance Efficiency over 18% , 2021, Advanced materials.
[15] Yuan Zhang,et al. Non-fullerene acceptors with branched side chains and improved molecular packing to exceed 18% efficiency in organic solar cells , 2021, Nature Energy.
[16] Haijun Fan,et al. Organic Solar Cells with 18% Efficiency Enabled by an Alloy Acceptor: A Two‐in‐One Strategy , 2021, Advanced materials.
[17] W. Ma,et al. A highly crystalline non-fullerene acceptor enabling efficient indoor organic photovoltaics with high EQE and fill factor , 2021 .
[18] Tao Wang,et al. Balancing the efficiency, stability, and cost potential for organic solar cells via a new figure of merit , 2021 .
[19] K. Wong,et al. Side‐Chain Engineering on Y‐Series Acceptors with Chlorinated End Groups Enables High‐Performance Organic Solar Cells , 2021, Advanced Energy Materials.
[20] Hongzheng Chen,et al. High-performance and eco-friendly semitransparent organic solar cells for greenhouse applications , 2021, Joule.
[21] Liyan Yu,et al. Achieving Efficient Ternary Organic Solar Cells Using Structurally Similar Non‐Fullerene Acceptors with Varying Flanking Side Chains , 2021, Advanced Energy Materials.
[22] Hongzheng Chen,et al. Layer‐by‐Layer Processed Ternary Organic Photovoltaics with Efficiency over 18% , 2021, Advanced materials.
[23] H. Ade,et al. Regio-Regular Polymer Acceptors Enabled by Determined Fluorination on End Groups for All-Polymer Solar Cells with 15.2% Efficiency. , 2021, Angewandte Chemie.
[24] M. Leclerc,et al. Low-Bandgap Non-fullerene Acceptors Enabling High-Performance Organic Solar Cells , 2021 .
[25] Yongfang Li,et al. Achieving 16.68% efficiency ternary as-cast organic solar cells , 2021, Science China Chemistry.
[26] Oskar J. Sandberg,et al. A History and Perspective of Non‐Fullerene Electron Acceptors for Organic Solar Cells , 2021, Advanced Energy Materials.
[27] H. Ade,et al. A molecular interaction–diffusion framework for predicting organic solar cell stability , 2021, Nature Materials.
[28] X. Zhan,et al. Fused-Ring Electron Acceptors for Photovoltaics and Beyond. , 2020, Accounts of chemical research.
[29] Top Archie Dela Peña,et al. Intrinsic efficiency limits in low-bandgap non-fullerene acceptor organic solar cells , 2020, Nature Materials.
[30] Feng He,et al. 17.1%-Efficient Eco-Compatible Organic Solar Cells from a Dissymmetric 3D Network Acceptor. , 2020, Angewandte Chemie.
[31] Yuze Lin,et al. Selenium Heterocyclic Electron Acceptor with Small Urbach Energy for As-Cast High-Performance Organic Solar Cells. , 2020, Journal of the American Chemical Society.
[32] H. Ade,et al. Optimized active layer morphologies via ternary copolymerization of polymer donors for 17.6% efficiency organic solar cells with enhanced fill factor. , 2020, Angewandte Chemie.
[33] Kai Chen,et al. Altering the Positions of Chlorine and Bromine Substitution on the End Group Enables High‐Performance Acceptor and Efficient Organic Solar Cells , 2020, Advanced Energy Materials.
[34] C. Brabec,et al. Material Strategies to Accelerate OPV Technology Toward a GW Technology , 2020, Advanced Energy Materials.
[35] K. Wong,et al. Enhanced hindrance from phenyl outer side chains on nonfullerene acceptor enables unprecedented simultaneous enhancement in organic solar cell performances with 16.7% efficiency , 2020, Nano Energy.
[36] Weihua Tang,et al. 2D Side‐Chain Engineered Asymmetric Acceptors Enabling Over 14% Efficiency and 75% Fill Factor Stable Organic Solar Cells , 2020, Advanced Functional Materials.
[37] F. Huang,et al. Single-Component Non-halogen Solvent-Processed High-Performance Organic Solar Cell Module with Efficiency over 14% , 2020 .
[38] C. Brabec,et al. The role of exciton lifetime for charge generation in organic solar cells at negligible energy-level offsets , 2020, Nature Energy.
[39] Daize Mo,et al. Synergistic Effect of Alkyl Chain and Chlorination Engineering on High-Performance Nonfullerene Acceptors. , 2020, ACS applied materials & interfaces.
[40] Xiaozhang Zhu,et al. n-Type Molecular Photovoltaic Materials: Design Strategies and Device Applications. , 2020, Journal of the American Chemical Society.
[41] Jianqi Zhang,et al. Single‐Junction Organic Photovoltaic Cells with Approaching 18% Efficiency , 2020, Advanced materials.
[42] Lee J. Richter,et al. Sub-picosecond charge-transfer at near-zero driving force in polymer:non-fullerene acceptor blends and bilayers , 2020, Nature Communications.
[43] Shangfeng Yang,et al. 18% Efficiency organic solar cells. , 2020, Science bulletin.
[44] H. Ade,et al. Alkyl Chain Tuning of Small Molecule Acceptors for Efficient Organic Solar Cells , 2019 .
[45] L. Meng,et al. Effects of Short‐Axis Alkoxy Substituents on Molecular Self‐Assembly and Photovoltaic Performance of Indacenodithiophene‐Based Acceptors , 2019, Advanced Functional Materials.
[46] X. Gu,et al. Aggregation‐Induced Multilength Scaled Morphology Enabling 11.76% Efficiency in All‐Polymer Solar Cells Using Printing Fabrication , 2019, Advanced materials.
[47] Yong Cui,et al. Eco‐Compatible Solvent‐Processed Organic Photovoltaic Cells with Over 16% Efficiency , 2019, Advanced materials.
[48] H. Ade,et al. Temperature‐Dependent Aggregation Donor Polymers Enable Highly Efficient Sequentially Processed Organic Photovoltaics Without the Need of Orthogonal Solvents , 2019, Advanced Functional Materials.
[49] Jacek Ulanski,et al. Single-Junction Organic Solar Cell with over 15% Efficiency Using Fused-Ring Acceptor with Electron-Deficient Core , 2019, Joule.
[50] Junxiang Zhang,et al. Effect of Isomerization on High-Performance Nonfullerene Electron Acceptors. , 2018, Journal of the American Chemical Society.
[51] He Yan,et al. Material insights and challenges for non-fullerene organic solar cells based on small molecular acceptors , 2018, Nature Energy.
[52] F. Liu,et al. Optimized Fibril Network Morphology by Precise Side‐Chain Engineering to Achieve High‐Performance Bulk‐Heterojunction Organic Solar Cells , 2018, Advanced materials.
[53] Jie Zhu,et al. Over 14% Efficiency in Polymer Solar Cells Enabled by a Chlorinated Polymer Donor , 2018, Advanced materials.
[54] Seth R. Marder,et al. Non-fullerene acceptors for organic solar cells , 2018 .
[55] Joshua H. Carpenter,et al. Quantitative relations between interaction parameter, miscibility and function in organic solar cells , 2018, Nature Materials.
[56] Yongfang Li,et al. Thieno[3,2-b]pyrrolo-Fused Pentacyclic Benzotriazole-Based Acceptor for Efficient Organic Photovoltaics. , 2017, ACS applied materials & interfaces.
[57] Daoben Zhu,et al. An Electron Acceptor Challenging Fullerenes for Efficient Polymer Solar Cells , 2015, Advanced materials.
[58] He Yan,et al. Aggregation and morphology control enables multiple cases of high-efficiency polymer solar cells , 2014, Nature Communications.
[59] A. Hexemer,et al. Direct measurements of exciton diffusion length limitations on organic solar cell performance. , 2012, Chemical communications.
[60] M. Kaltenbrunner,et al. Ultrathin and lightweight organic solar cells with high flexibility , 2012, Nature Communications.
[61] Wei Lin Leong,et al. Differential Resistance Analysis of Charge Carrier Losses in Organic Bulk Heterojunction Solar Cells: Observing the Transition from Bimolecular to Trap‐Assisted Recombination and Quantifying the Order of Recombination , 2011 .
[62] Christoph J. Brabec,et al. Recombination and loss analysis in polythiophene based bulk heterojunction photodetectors , 2002 .