Electrostatic force promoted intermolecular stacking of polymer donors toward 19.4% efficiency binary organic solar cells.
Zirui GanLiang WangJinlong CaiChuanhang GuoChen ChenDonghui LiYiwei FuBojun ZhouYuandong SunChenhao LiuJing ZhouDan LiuWei LiTao WangPublished in: Nature communications (2023)
Conjugated polymers are generally featured with low structural order due to their aromatic and irregular structural units, which limits their light absorption and charge mobility in organic solar cells. In this work, we report a conjugated molecule INMB-F that can act as a molecular bridge via electrostatic force to enhance the intermolecular stacking of BDT-based polymer donors toward efficient and stable organic solar cells. Molecular dynamics simulations and synchrotron X-ray measurements reveal that the electronegative INMB-F adsorb on the electropositive main chain of polymer donors to increase the donor-donor interactions, leading to enhanced structural order with shortened π-π stacking distance and consequently enhanced charge transport ability. Casting the non-fullerene acceptor layer on top of the INMB-F modified donor layer to fabricate solar cells via layer-by-layer deposition evidences significant power conversion efficiency boosts in a range of photovoltaic systems. A power conversion efficiency of 19.4% (certified 18.96%) is realized in PM6/L8-BO binary devices, which is one of the highest reported efficiencies of this material system. The enhanced structural order of polymer donors by INMB-F also leads to a six-fold enhancement of the operational stability of PM6/L8-BO organic solar cells.
Keyphrases
- solar cells
- molecular dynamics simulations
- water soluble
- kidney transplantation
- single molecule
- particulate matter
- air pollution
- molecular docking
- photodynamic therapy
- ionic liquid
- heavy metals
- magnetic resonance imaging
- high resolution
- single cell
- mass spectrometry
- gene expression
- magnetic resonance
- dna methylation
- dual energy
- energy transfer