An increase of the photoactive layer thickness in an organic solar cell is essential to improve photocurrent and hence the power conversion efficiency. However, thickening the photoactive layer always brings about a significant decrease in the fill factor due to the low charge carrier mobility of the organic semiconductor. Thus, to overcome the trade-off between thick film and fill factor, it is important to develop organic semiconductors with high charge carrier mobility in particular through the film thickness.
Here, we show that a new polymer based on dithienonaphthobisthiadiazole (TNT) demonstrated significantly high fill factors of around 0.8 with thick films of close to 300 nm in fullerene-based cells, which are among the highest values for thick organic solar cells. Further, the maximum power conversion efficiency of close to 12% was observed at a thickness of more than 400 nm. The polymer/fullerene blend film showed high hole mobilities in the order of 10^–2 cm²/Vs based on the space-charge limited current model, which accounted for the suppressed bimolecular recombination. The high hole mobility likely originated in the extremely large π–π overlap between the TNT moieties in the π-stacked polymer chains, as suggested by the crystal structure of the model compound. We will also discuss the structure-property relationship of TNT-based polymer in comparison with its counterpart, naphthobisthiadiazole (NTz)-based polymer.