Non-fullerene acceptors with branched side chains and improved molecular packing to exceed 18% efficiency in organic solar cells
暂无分享,去创建一个
Yuan Zhang | Yanming Sun | D. Wei | Jiadong Zhou | Feng Liu | J. Min | H. Yan | Yuanping Yi | Lei Zhu | Zengqi Xie | Xuning Zhang | Guangchao Han | Jiali Song | Jing Guo | Jinqiu Xu | Chao Li | Huotian Zhang | Fen-e. Gao | G. Han | F. Gao
[1] Yong Cao,et al. High-efficiency organic solar cells with low non-radiative recombination loss and low energetic disorder , 2020, Nature Photonics.
[2] Hongzheng Chen,et al. New Phase for Organic Solar Cell Research: Emergence of Y-Series Electron Acceptors and Their Perspectives , 2020 .
[3] M. Zhang,et al. Efficient Organic Solar Cell with 16.88% Efficiency Enabled by Refined Acceptor Crystallization and Morphology with Improved Charge Transfer and Transport Properties , 2020, Advanced Energy Materials.
[4] A. Jen,et al. Graphdiyne Derivative as Multifunctional Solid Additive in Binary Organic Solar Cells with 17.3% Efficiency and High Reproductivity , 2020, Advanced materials.
[5] Shangfeng Yang,et al. 18% Efficiency organic solar cells. , 2020, Science bulletin.
[6] H. Ade,et al. Alkyl Chain Tuning of Small Molecule Acceptors for Efficient Organic Solar Cells , 2019 .
[7] Xiaozhang Zhu,et al. Subtle Molecular Tailoring Induces Significant Morphology Optimization Enabling over 16% Efficiency Organic Solar Cells with Efficient Charge Generation , 2019, Advanced materials.
[8] X. Hao,et al. Ternary Organic Solar Cells with Efficiency >16.5% Based on Two Compatible Nonfullerene Acceptors , 2019, Advanced materials.
[9] L. Meng,et al. Achieving Fast Charge Separation and Low Nonradiative Recombination Loss by Rational Fluorination for High‐Efficiency Polymer Solar Cells , 2019, Advanced materials.
[10] B. Liu,et al. A monothiophene unit incorporating both fluoro and ester substitution enabling high-performance donor polymers for non-fullerene solar cells with 16.4% efficiency , 2019, Energy & Environmental Science.
[11] Ruixiang Peng,et al. 16.67% Rigid and 14.06% Flexible Organic Solar Cells Enabled by Ternary Heterojunction Strategy , 2019, Advanced materials.
[12] Yong Cui,et al. Eco‐Compatible Solvent‐Processed Organic Photovoltaic Cells with Over 16% Efficiency , 2019, Advanced materials.
[13] Yong Cui,et al. Improved Charge Transport and Reduced Nonradiative Energy Loss Enable Over 16% Efficiency in Ternary Polymer Solar Cells , 2019, Advanced materials.
[14] Zhishan Bo,et al. Noncovalently fused-ring electron acceptors with near-infrared absorption for high-performance organic solar cells , 2019, Nature Communications.
[15] Wei Ma,et al. Single‐Junction Polymer Solar Cells with 16.35% Efficiency Enabled by a Platinum(II) Complexation Strategy , 2019, Advanced materials.
[16] F. Gao,et al. Over 16% efficiency organic photovoltaic cells enabled by a chlorinated acceptor with increased open-circuit voltages , 2019, Nature Communications.
[17] Hongzheng Chen,et al. Simple non-fused electron acceptors for efficient and stable organic solar cells , 2019, Nature Communications.
[18] Yanming Sun,et al. Asymmetric Nonfullerene Small Molecule Acceptors for Organic Solar Cells , 2019, Advanced Energy Materials.
[19] Yanming Sun,et al. Optimal bulk-heterojunction morphology enabled by fibril network strategy for high-performance organic solar cells , 2019, Science China Chemistry.
[20] Jacek Ulanski,et al. Single-Junction Organic Solar Cell with over 15% Efficiency Using Fused-Ring Acceptor with Electron-Deficient Core , 2019, Joule.
[21] Christoph J. Brabec,et al. Critical review of the molecular design progress in non-fullerene electron acceptors towards commercially viable organic solar cells. , 2019, Chemical Society reviews.
[22] Simplified synthetic routes for low cost and high photovoltaic performance n-type organic semiconductor acceptors , 2019, Nature Communications.
[23] Henk J. Bolink,et al. Effects of Masking on Open-Circuit Voltage and Fill Factor in Solar Cells , 2019, Joule.
[24] Thomas Kirchartz,et al. Optical Gaps of Organic Solar Cells as a Reference for Comparing Voltage Losses , 2018, Advanced Energy Materials.
[25] Yong Cao,et al. Organic and solution-processed tandem solar cells with 17.3% efficiency , 2018, Science.
[26] Feng Liu,et al. High-efficiency small-molecule ternary solar cells with a hierarchical morphology enabled by synergizing fullerene and non-fullerene acceptors , 2018, Nature Energy.
[27] Yang Yang,et al. Next-generation organic photovoltaics based on non-fullerene acceptors , 2018 .
[28] He Yan,et al. Design rules for minimizing voltage losses in high-efficiency organic solar cells , 2018, Nature Materials.
[29] He Yan,et al. Material insights and challenges for non-fullerene organic solar cells based on small molecular acceptors , 2018, Nature Energy.
[30] 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.
[31] C. Zhong,et al. Asymmetrical Ladder‐Type Donor‐Induced Polar Small Molecule Acceptor to Promote Fill Factors Approaching 77% for High‐Performance Nonfullerene Polymer Solar Cells , 2018, Advanced materials.
[32] Fei Huang,et al. Nonfullerene Acceptor Molecules for Bulk Heterojunction Organic Solar Cells. , 2018, Chemical reviews.
[33] Fujun Zhang,et al. Dithieno[3,2‐b:2′,3′‐d]pyrrol Fused Nonfullerene Acceptors Enabling Over 13% Efficiency for Organic Solar Cells , 2018, Advanced materials.
[34] C. McNeill,et al. An Alkylated Indacenodithieno[3,2‐b]thiophene‐Based Nonfullerene Acceptor with High Crystallinity Exhibiting Single Junction Solar Cell Efficiencies Greater than 13% with Low Voltage Losses , 2018, Advanced materials.
[35] Seth R. Marder,et al. Non-fullerene acceptors for organic solar cells , 2018 .
[36] Feng Gao,et al. Organic solar cells based on non-fullerene acceptors. , 2018, Nature materials.
[37] D. Neher,et al. Reducing Voltage Losses in Cascade Organic Solar Cells while Maintaining High External Quantum Efficiencies , 2017 .
[38] Richard H. Friend,et al. Understanding Energy Loss in Organic Solar Cells: Toward a New Efficiency Regime , 2017 .
[39] Yun Zhang,et al. Molecular Optimization Enables over 13% Efficiency in Organic Solar Cells. , 2017, Journal of the American Chemical Society.
[40] H. Ade,et al. Fast charge separation in a non-fullerene organic solar cell with a small driving force , 2016, Nature Energy.
[41] Yanming Sun,et al. A Facile Planar Fused-Ring Electron Acceptor for As-Cast Polymer Solar Cells with 8.71% Efficiency. , 2016, Journal of the American Chemical Society.
[42] Itaru Osaka,et al. High-efficiency polymer solar cells with small photon energy loss , 2015, Nature Communications.
[43] Daoben Zhu,et al. An Electron Acceptor Challenging Fullerenes for Efficient Polymer Solar Cells , 2015, Advanced materials.
[44] Thomas Kirchartz,et al. Quantifying Losses in Open-Circuit Voltage in Solution-Processable Solar Cells , 2015 .
[45] M. Toney,et al. A general relationship between disorder, aggregation and charge transport in conjugated polymers. , 2013, Nature materials.
[46] R. J. Kline,et al. Quantitative analysis of lattice disorder and crystallite size in organic semiconductor thin films , 2011 .
[47] K. Emery,et al. Accurate measurement of organic solar cell efficiency , 2008, Organic Photonics + Electronics.
[48] H. Queisser,et al. Detailed Balance Limit of Efficiency of p‐n Junction Solar Cells , 1961 .