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Unraveling non-radiative decay channels of exciplexes to construct efficient red emitters for organic light-emitting diodes.

Heng-Yuan ZhangMing ZhangHao ZhuoHao-Yu YangBo HanYong-Hao ZhengHui WangHui LinSi-Lu TaoCai-Jun ZhengXiao-Hong Zhang
Published in: Chemical science (2024)
Exciplex emitters naturally have thermally activated delayed fluorescence characteristics due to their spatially separated molecular orbitals. However, the intermolecular charge transfer potentially induces diverse non-radiative decay channels, severely hindering the construction of efficient red exciplexes. Thus, a thorough comprehension of this energy loss is of paramount importance. Herein, different factors, including molecular rigidity, donor-acceptor interactions and donor-donor/acceptor-acceptor interactions, that impact the non-radiative decay were systematically investigated using contrasting exciplex emitters. The exciplex with rigid components and intermolecular hydrogen bonds showed a photoluminescence quantum yield of 84.1% and a singlet non-radiative decay rate of 1.98 × 10 6 s -1 at an optimized mixing ratio, respectively, achieving a 3.3-fold increase and a 70% decrease compared to the comparison group. In the electroluminescent device, a maximum external quantum efficiency of 23.8% was achieved with an emission peak of 608 nm, which represents the state-of-the-art organic light-emitting diodes using exciplex emitters. Accordingly, a new strategy is finally proposed, exploiting system rigidification to construct efficient red exciplex emitters that suppress non-radiative decay.
Keyphrases
  • light emitting
  • energy transfer
  • quantum dots
  • solar cells
  • single molecule
  • molecular dynamics
  • atomic force microscopy