Impact of Fullerene on the Photophysics of Ternary Small Molecule Organic Solar Cells
SAFAKATH KARUTHEDATH a, Yuliar Firdaus a, Ru-Ze Liang a, Julien Gorenflot a, Pierre M. Beaujuge a, Thomas D. Anthopoulos a, Frédéric Laquai a
a King Abdullah University of Science and Technology (KAUST) - Saudi Arabia, 4700 King Abdullah University of Science and Technology (KAUST), Thuwal, Saudi Arabia
Materials for Sustainable Development Conference (MATSUS)
Proceedings of nanoGe Fall Meeting19 (NFM19)
#OPV19. Organic Photovoltaics: recent breakthroughs, advanced characterization and modelling
Berlin, Germany, 2019 November 3rd - 8th
Organizers: Jörg Ackermann and Uli Würfel
Oral, SAFAKATH KARUTHEDATH, presentation 108
DOI: https://doi.org/10.29363/nanoge.nfm.2019.108
Publication date: 18th July 2019

Ternary organic solar cells (OSC) are among the best-performing organic photovoltaic devices to date, largely due to the recent development of non-fullerene acceptors.[1] However, fullerene molecules still play an important role in ternary OSC systems, since, for reasons not well understood, they often improve the device performance, despite their lack of absorption.[2] In this work, we study the photophysics of a prototypical ternary small molecule OSC blend composed of the donor DR3, the non-fullerene acceptor ICC6, and the fullerene derivative PC71BM by ultrafast spectroscopy. Surprisingly, we find that after excitation of PC71BM, ultrafast singlet energy transfer to ICC6 competes efficiently with charge transfer. Subsequently, singlets on ICC6 undergo hole transfer to DR3, resulting in free charge generation. Interestingly, PC71BM improves indirectly the electron mobility of the ternary blend, while electrons reside predominantly in ICC6 domains as indicated by fast spectroscopy. The improved mobility facilitates charge carrier extraction, in turn leading to higher device efficiencies of the ternary compared to binary solar cells. Using the (photo)physical parameters obtained from (transient) spectroscopy and charge transport measurements, we simulate the device’s current-voltage characteristics and demonstrate that the parameters accurately reproduce the experimentally-measured device performance

The research reported in this publication was supported by funding from King Abdullah University of Science and Technology (KAUST).

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