Industrial viability of single-component organic solar cells

[1]  C. Brabec,et al.  Unraveling the Charge‐Carrier Dynamics from the Femtosecond to the Microsecond Time Scale in Double‐Cable Polymer‐Based Single‐Component Organic Solar Cells , 2021, Advanced Energy Materials.

[2]  Jianhui Hou,et al.  Tandem Organic Solar Cell with 20.2% Efficiency , 2021, Joule.

[3]  J. Roncali Single‐Material Organic Solar Cells Based on Small Molecule Homojunctions: An Outdated Concept or a New Challenge for the Chemistry and Physics of Organic Photovoltaics? , 2021, Advanced Energy Materials.

[4]  C. McNeill,et al.  Revealing the Side-Chain Dependent Ordering Transition of Highly-Crystalline Double-Cable Conjugated Polymers. , 2021, Angewandte Chemie.

[5]  S. Forrest,et al.  Non-fullerene acceptor organic photovoltaics with intrinsic operational lifetimes over 30 years , 2021, Nature Communications.

[6]  C. Brabec,et al.  Molecular Oligothiophene–Fullerene Dyad Reaching Over 5% Efficiency in Single‐Material Organic Solar Cells , 2021, Advanced materials.

[7]  Yuanyuan Hu,et al.  Narrow‐Bandgap Single‐Component Polymer Solar Cells with Approaching 9% Efficiency , 2021, Advanced materials.

[8]  Tao Wang,et al.  A conjugated donor-acceptor block copolymer enables over 11% efficiency for single-component polymer solar cells , 2021, Joule.

[9]  C. Brabec,et al.  Single-Component Organic Solar Cells with Competitive Performance , 2021, Organic Materials.

[10]  N. Gasparini,et al.  Challenges to the Success of Commercial Organic Photovoltaic Products , 2021, Advanced Energy Materials.

[11]  F. Gao,et al.  16% efficiency all-polymer organic solar cells enabled by a finely tuned morphology via the design of ternary blend , 2021 .

[12]  A. Jen,et al.  High Efficiency (15.8%) All-Polymer Solar Cells Enabled by a Regioregular Narrow Bandgap Polymer Acceptor. , 2021, Journal of the American Chemical Society.

[13]  R. Zhu,et al.  Revealing photo-degradation mechanism of PM6:Y6 based high-efficiency organic solar cells , 2021, Journal of Materials Chemistry C.

[14]  C. Brabec,et al.  Molecular Donor–Acceptor Dyads for Efficient Single‐Material Organic Solar Cells , 2020 .

[15]  H. Ade,et al.  Balanced Charge Transport Optimizes Industry‐Relevant Ternary Polymer Solar Cells , 2020, Solar RRL.

[16]  Tae Geun Kim,et al.  Rational design of a main chain conjugated copolymer having donor–acceptor heterojunctions and its application in indoor photovoltaic cells , 2020 .

[17]  C. Brabec,et al.  Material Strategies to Accelerate OPV Technology Toward a GW Technology , 2020, Advanced Energy Materials.

[18]  Weiwei Li,et al.  Miscibility‐Controlled Phase Separation in Double‐Cable Conjugated Polymers for Single‐Component Organic Solar Cells with Efficiencies over 8 % , 2020, Angewandte Chemie.

[19]  S. Mannsfeld,et al.  Orientation dependent molecular electrostatics drives efficient charge generation in homojunction organic solar cells , 2020, Nature Communications.

[20]  H. Yip,et al.  Exploiting Ternary Blends for Improved Photostability in High-Efficiency Organic Solar Cells , 2020 .

[21]  Yong Cao,et al.  Improved Average Figure‐of‐Merit of High‐Efficiency Nonfullerene Solar Cells via Minor Combinatory Side Chain Approach , 2020 .

[22]  C. Brabec,et al.  Unraveling the Microstructure‐Related Device Stability for Polymer Solar Cells Based on Nonfullerene Small‐Molecular Acceptors , 2020, Advanced materials.

[23]  Weiwei Li,et al.  A selenophene substituted double-cable conjugated polymer enables efficient single-component organic solar cells , 2020, Journal of Materials Chemistry C.

[24]  Young Woong Lee,et al.  Significantly Improved Morphology and Efficiency of Nonhalogenated Solvent‐Processed Solar Cells Derived from a Conjugated Donor–Acceptor Block Copolymer , 2020, Advanced science.

[25]  Kai Zhu,et al.  Consensus statement for stability assessment and reporting for perovskite photovoltaics based on ISOS procedures , 2020, Nature Energy.

[26]  Weiwei Li,et al.  Correlating crystallinity to photovoltaic performance in single-component organic solar cells via conjugated backbone engineering , 2019, Dyes and Pigments.

[27]  Ruipeng Li,et al.  A zinc(ii) complex of di(naphthylethynyl)azadipyrromethene with low synthetic complexity leads to OPV with high industrial accessibility , 2019, Journal of Materials Chemistry A.

[28]  P. Samorí,et al.  Covalently linked donor-acceptor dyad for efficient single material organic solar cells. , 2019, Chemical communications.

[29]  C. Brabec,et al.  Revealing Hidden UV Instabilities in Organic Solar Cells by Correlating Device and Material Stability , 2019, Advanced Energy Materials.

[30]  Stephen R. Forrest,et al.  Intrinsically stable organic solar cells under high-intensity illumination , 2019, Nature.

[31]  Fan Yang,et al.  Conjugated molecular dyads with diketopyrrolopyrrole-based conjugated backbones for single-component organic solar cells , 2019, Materials Chemistry Frontiers.

[32]  C. Brabec,et al.  Thermal-Driven Phase Separation of Double-Cable Polymers Enables Efficient Single-Component Organic Solar Cells , 2019, Joule.

[33]  C. Brabec,et al.  Comprehensive Investigation and Analysis of Bulk-Heterojunction Microstructure of High-Performance PCE11:PCBM Solar Cells. , 2019, ACS applied materials & interfaces.

[34]  Jacek Ulanski,et al.  Single-Junction Organic Solar Cell with over 15% Efficiency Using Fused-Ring Acceptor with Electron-Deficient Core , 2019, Joule.

[35]  C. Brabec,et al.  Evidencing Excellent Thermal‐ and Photostability for Single‐Component Organic Solar Cells with Inherently Built‐In Microstructure , 2019, Advanced Energy Materials.

[36]  Christoph J. Brabec,et al.  A top-down strategy identifying molecular phase stabilizers to overcome microstructure instabilities in organic solar cells , 2019, Energy & Environmental Science.

[37]  J. Roncali,et al.  The Dawn of Single Material Organic Solar Cells , 2018, Advanced science.

[38]  C. Brabec,et al.  Analyzing the efficiency, stability and cost potential for fullerene-free organic photovoltaics in one figure of merit , 2018 .

[39]  Chang Geun Park,et al.  High-Performance Polymer Solar Cell with Single Active Material of Fully Conjugated Block Copolymer Composed of Wide-Band gap Donor and Narrow-Band gap Acceptor Blocks. , 2018, ACS applied materials & interfaces.

[40]  Fan Yang,et al.  "Double-Cable" Conjugated Polymers with Linear Backbone toward High Quantum Efficiencies in Single-Component Polymer Solar Cells. , 2017, Journal of the American Chemical Society.

[41]  Thanh Luan Nguyen,et al.  Single Component Organic Solar Cells Based on Oligothiophene‐Fullerene Conjugate , 2017 .

[42]  Christoph J. Brabec,et al.  Evaluation of Electron Donor Materials for Solution‐Processed Organic Solar Cells via a Novel Figure of Merit , 2017 .

[43]  L. Lüer,et al.  Stability of Organic Solar Cells: The Influence of Nanostructured Carbon Materials , 2017 .

[44]  Michael D. McGehee,et al.  Progress in Understanding Degradation Mechanisms and Improving Stability in Organic Photovoltaics , 2017, Advanced materials.

[45]  C. J. M. Emmott,et al.  Reducing the efficiency-stability-cost gap of organic photovoltaics with highly efficient and stable small molecule acceptor ternary solar cells. , 2017, Nature materials.

[46]  Christoph J. Brabec,et al.  Abnormal strong burn-in degradation of highly efficient polymer solar cells caused by spinodal donor-acceptor demixing , 2017, Nature Communications.

[47]  C. Brabec,et al.  Fully Solution‐Processed Small Molecule Semitransparent Solar Cells: Optimization of Transparent Cathode Architecture and Four Absorbing Layers , 2016 .

[48]  C. Brabec,et al.  Morphological and electrical control of fullerene dimerization determines organic photovoltaic stability , 2016 .

[49]  Liyuan Han,et al.  Manganese powder promoted highly efficient and selective synthesis of fullerene mono- and biscycloadducts at room temperature , 2015, Scientific Reports.

[50]  J. Nelson,et al.  Models of charge pair generation in organic solar cells. , 2015, Physical chemistry chemical physics : PCCP.

[51]  Gabriele Bianchi,et al.  “All That Glisters Is Not Gold”: An Analysis of the Synthetic Complexity of Efficient Polymer Donors for Polymer Solar Cells , 2015 .

[52]  Timothy M. Burke,et al.  Reducing burn-in voltage loss in polymer solar cells by increasing the polymer crystallinity , 2014 .

[53]  Jianzhang Zhao,et al.  Room-temperature long-lived triplet excited states of naphthalenediimides and their applications as organic triplet photosensitizers for photooxidation and triplet-triplet annihilation upconversions. , 2012, The Journal of organic chemistry.

[54]  J. Roncali Single Material Solar Cells: the Next Frontier for Organic Photovoltaics? , 2011 .

[55]  Mukundan Thelakkat,et al.  Swallow-tail substituted liquid crystalline perylene bisimides: synthesis and thermotropic properties. , 2009, Journal of the American Chemical Society.

[56]  Jin Young Kim,et al.  Processing additives for improved efficiency from bulk heterojunction solar cells. , 2008, Journal of the American Chemical Society.

[57]  Yongfang Li,et al.  Synthesis and Photovoltaic Properties of a Donor-Acceptor Double-Cable Polythiophene with High Content of C60 Pendant , 2007 .

[58]  M. Thelakkat,et al.  Fluorescent dye-labeled polymers carrying triphenylamine, styrene, or acrylate pendant groups , 2006 .

[59]  M. Maggini,et al.  Soluble polythiophenes with pendant fullerene groups as double cable materials for photodiodes , 2001 .

[60]  J. Hummelen,et al.  Photoinduced electron transfer and photovoltaic devices of a conjugated polymer with pendant fullerenes. , 2001, Journal of the American Chemical Society.

[61]  C. Brabec,et al.  Plastic Solar Cells , 2001 .