%0 Journal Article %1 Luo_2020 %A Luo, Yinqi %A Fang, Shaomao %A Zheng, Nan %A Liu, Linlin %A Würthner, Frank %A Xie, Zengqi %D 2020 %I American Chemical Society (ACS) %J ACS Appl. Energy Mater. %K myown %N 2 %P 1694--1701 %R 10.1021/acsaem.9b02176 %T Increased Electron Transport and Hole Blocking in an Aqueous Solution Processed Dye-Doped ZnO Cathode Interlayer for High Performance Organic Solar Cells %U https://doi.org/10.1021%2Facsaem.9b02176 %V 3 %X In this work, we report high electron transport and hole blocking capability of hybrid photoconductive interlayer materials manufactured from an aqueous solution, which are achieved by doping perylene bisimide dyes into zinc oxide (ZnO) through the formation of ionic bonding between the organic dopants and the inorganic matrix. Benzenesulfonic acid functional groups are introduced to perylene bisimide dye molecules, which enhance the solubility of the dye molecules in water and form ionic bonds with zinc atoms during the fabrication of the hybrid thin films. The ionic bonding assisted molecular dispersion endows the hybrid thin film with full photoconductive properties, which improves electron transport by photoinduced electron transfer from organic dye molecules to the conduction band of ZnO. Especially, the hole blocking ability is also highly increased. Both increased electron transport and hole blocking are benefits to the charge selectivity of the cathode interlayer, which results in a high fill factor in organic solar cells. A power conversion efficiency of up to 15.4% is achieved on the basis of such an aqueous solution processed hybrid interlayer when using PM6:Y6 as the active layer. In addition, the optimized thermal annealing temperature for the fabrication of the hybrid thin film is as low as 150 °C, which is a benefit for the application of such photoconductive materials in flexible devices.

@article{Luo_2020, abstract = {In this work, we report high electron transport and hole blocking capability of hybrid photoconductive interlayer materials manufactured from an aqueous solution, which are achieved by doping perylene bisimide dyes into zinc oxide (ZnO) through the formation of ionic bonding between the organic dopants and the inorganic matrix. Benzenesulfonic acid functional groups are introduced to perylene bisimide dye molecules, which enhance the solubility of the dye molecules in water and form ionic bonds with zinc atoms during the fabrication of the hybrid thin films. The ionic bonding assisted molecular dispersion endows the hybrid thin film with full photoconductive properties, which improves electron transport by photoinduced electron transfer from organic dye molecules to the conduction band of ZnO. Especially, the hole blocking ability is also highly increased. Both increased electron transport and hole blocking are benefits to the charge selectivity of the cathode interlayer, which results in a high fill factor in organic solar cells. A power conversion efficiency of up to 15.4% is achieved on the basis of such an aqueous solution processed hybrid interlayer when using PM6:Y6 as the active layer. In addition, the optimized thermal annealing temperature for the fabrication of the hybrid thin film is as low as 150 °C, which is a benefit for the application of such photoconductive materials in flexible devices.}, added-at = {2020-02-24T15:27:14.000+0100}, author = {Luo, Yinqi and Fang, Shaomao and Zheng, Nan and Liu, Linlin and Würthner, Frank and Xie, Zengqi}, biburl = {https://www.bibsonomy.org/bibtex/2931205bc6e73c76503231773faa52c8a/wuerthner_group}, doi = {10.1021/acsaem.9b02176}, interhash = {fbfab0e89308a1d01ebf0261aed3ce0c}, intrahash = {931205bc6e73c76503231773faa52c8a}, journal = {ACS Appl. Energy Mater.}, keywords = {myown}, month = jan, number = 2, pages = {1694--1701}, publisher = {American Chemical Society (ACS)}, timestamp = {2023-05-30T09:46:44.000+0200}, title = {Increased Electron Transport and Hole Blocking in an Aqueous Solution Processed Dye-Doped ZnO Cathode Interlayer for High Performance Organic Solar Cells}, url = {https://doi.org/10.1021%2Facsaem.9b02176}, volume = 3, year = 2020 }