Abstract
For efficient colloidal quantum dot (CQD) solar cells (CQD-SCs), thiol-passivated p-type CQDs are generally used as a hole-transporting material (HTM); however, there are issues with the control of optoelectrical properties, low thiol passivation rate, and poor morphology with a power conversion efficiency (PCE) of approximately 11%. Although polymeric HTMs have been introduced to address these issues, maximizing efficiency and achieving green-solvent processability and thermal stability for commercialization is necessary. Here, we synthesize a novel benzodifuran (BDF)-based HTM (asy-ranPBTBDF) showing an electron-deficient state, low steric hindrance, and low planarity compared to those of a typical benzodithiophene (BDT)-based HTM (asy-ranPBTBDT). BDF properties lead to deep high occupied molecular orbital (HOMO) levels, close π–π stacking, excellent solubility, and amorphous properties related to efficiency, green-solvent processability, and thermal stability. With these benefits, the asy-ranPBTBDF-based CQD-SC showed enhanced open-circuit voltage (VOC) (0.65 V) and PCE (13.29%) compared to those of the asy-ranPBTBDT-based device (0.63 V and 12.22%) in toxic processes with chlorobenzene. The asy-ranPBTBDF-based CQD-SC showed a PCE of 12.51% in a green-solvent process with 2-methylanisole and improved thermal stability at 80 °C (83.8% retaining after 24 h) owing to less lateral crystallization than the asy-ranPBTBDT-based device (60.8% retaining after 24 h).
Original language | English |
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Article number | e12408 |
Journal | Energy and Environmental Materials |
Volume | 6 |
Issue number | 5 |
DOIs | |
State | Published - Sep 2023 |
Externally published | Yes |
Keywords
- colloidal quantum dot
- green-solvent
- photovoltaics
- semiconducting polymers
- stability