Interfacial modification of LiF-incorporated MnO2 mixed P3HT:PC60BM-based organic photoactive layer

Interfacial charge transfer in the photoactive layer plays an essential role in determining device performance in organic photovoltaics. Recently, numerous studies have reported interfacial modification by incorporating inorganic nanostructures into the bulk heterojunction photoactive layer, with th...

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Bibliographic Details
Published in:Optical materials 2023-10, Vol.144, p.114340, Article 114340
Main Authors: Hong, Kai Jeat, Tan, Sin Tee, Lau, Kam Sheng, Yap, Chi Chin, Tan, Chun Hui, Low, Yiin Jian, Liew, Josephine Ying Chyi, Chia, Chin Hua, Chong, Kok-Keong
Format: Article
Language:English
Subjects:
Charge transfer
Fluoride
Interface
MnO2
Organic photoactive layer
Passivation
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Summary:Interfacial charge transfer in the photoactive layer plays an essential role in determining device performance in organic photovoltaics. Recently, numerous studies have reported interfacial modification by incorporating inorganic nanostructures into the bulk heterojunction photoactive layer, with the aim of increasing the interfacial area to improve charge transfer efficiency. However, there is limited understanding of in-depth defect analysis and the charge transfer mechanism. In this report, different weight percentages of LiF were incorporated into MnO2 (LMO) mixed photoactive layers. The robust relationship between charge transport dynamics and defect density of the device in the presence of LiF is elucidated. The results show that the photoactive layer with 10.0 wt% LMO exhibited a 41% improvement in device performance compared to that of pristine P3HT:PC60BM, with a power conversion efficiency (PCE), open-circuit voltage (Voc), short-circuit current density (Jsc), and fill factor (FF) of 2.43%, 0.52 V, 9.77 mA/cm2, and 0.48, respectively. The photovoltaic performance improvement can be attributed to (i) the efficient charge transfer properties in the 10.0 wt% LMO, as evidenced by the suppressed S 2p and intensified O=C in X-ray photoelectron spectroscopy (XPS) analysis, and (ii) the low carrier recombination due to the success of LiF as a surface passivation agent, as indicated by 53% photoluminescence quenching. This report provides a fundamental understanding and offers an alternative solution for designing high-efficiency organic photovoltaics in the near future. •10.0 wt% LMO based OPV presented a 34% improvement in Jsc.•10.0 wt% LMO has recorded 53% of photoluminescence quenching.•10.0 wt% LMO showed 25% P3HT planarity improvement.
ISSN:0925-3467
1873-1252
DOI:10.1016/j.optmat.2023.114340