Newly
synthesized perylene diimide dimers were investigated as
nonfullerene electron acceptors for organic solar cells. In particular,
two analogous positional isomers exhibiting twisted vs planar geometries
were prepared to make a direct comparison of their optical and electronic
properties. These properties were investigated to provide information
regarding the impact of the nonfullerene acceptor geometry on the
ultimate photovoltaic performance. The two isomers exhibited strikingly
different optical and photophysical properties in solution as well
as in film. The ultrafast spectroscopic investigation in solution
revealed the occurrence of charge transfer upon photoexcitation, which
takes place more efficiently in the planar isomer. This is also supported
by theoretical simulations. The planar conformation exhibits higher
aggregation in the neat film as well as in the blend. However, our
results suggest that the dominance of intramolecular charge transfer
in the planar isomer is the crucial factor in determining the improved
power conversion efficiency of organic solar cells.
This paper describes the synthesis and application of βTPB6 and βTPB6-C as electron acceptors for organic solar cells. Compound βTPB6 contains four covalently bonded PDIs with a BDT-Th core at the β-position. The free rotation of PDIs renders βTPB6 with varying molecular geometries. The cyclization of βTPB6 yields βTPB6-C with high rigidity of the molecular geometry and enlarged conjugated skeleton. The inverted solar cells based on βTPB6-C and PTB7-Th as the donor polymer exhibited the highest efficiency of 7.69% with V oc of 0.92 V, J sc of 14.9 mAcm −2 , and FF of 0.56, which is 31% higher than that for βTPB6 based devices. The larger fraction of βTPB6-C and PTB7-Th than that of βTPB6:PTB7-Th in a blend film takes a face-on orientation packing pattern for π-systems that benefits the charge transport and hence higher PCE value than that for βTPB6:PTB7-Th. It was also found that a proper DIO:DPE additive further enhances this trend, which results in an increase of the PCE value for βTPB6-C:PTB7-Th while decreasing the PCE value for βTPB6:PTB7-Th.
A critical issue in developing high-performance organic light-emitting transistors (OLETs) is to balance the trade-off between charge transport and light emission in a semiconducting material. Although traditional materials for organic...
The lack of design principle for
developing high-performance polymer
materials displaying strong fluorescence and high ambipolar charge
mobilities limited their performance in organic light-emitting transistors
(OLETs), electrically pumped organic laser, and other advanced electronic
devices. A series of semiladder polymers by copolymerization of weak
acceptors (TPTQ or TPTI) and weak donors (fluorene (F) or carbazole
(C)) have been developed for luminescent and charge transporting properties.
It was found that enhanced planarity, high crystallinity, and a delicate
balance in interchain aggregation obtained in the new copolymer, TPTQ-F,
contributed to high ambipolar charge mobilities and photoluminescent
quantum yield. TPTQ-F showed excellent performance in solution-processed
multilayered OLET devices with an external quantum efficiency (EQE)
of 5.3%.
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