English

Highly efficient light-emitting diodes based on intramolecular rotation

Materials Science 2018-04-18 v1 Mesoscale and Nanoscale Physics Optics

Abstract

The efficiency of an organic light-emitting diode (OLED) is fundamentally governed by the spin of recombining electron-hole pairs (singlet and triplet excitons), since triplets cannot usually emit light. The singlet-triplet energy gap, a key factor for efficient utilization of triplets, is normally positive. Here we show that in a family of materials with amide donor and carbene acceptor moieties linked by a metal, this energy gap for singlet and triplet excitons with charge-transfer character can be tuned from positive to negative values via the rotation of donor and acceptor about the metal-amide bond. When the gap is close to zero, facile intersystem crossing is possible, enabling efficient emission from singlet excitons. We demonstrate solution-processed LEDs with exceptionally high quantum efficiencies (near-100% internal and >27% external quantum efficiencies), and current and power efficiencies (87 cd/A and 75 lm/W) comparable to, or exceeding, those of state-of-the-art vacuum-processed OLEDs and quantum dot LEDs.

Keywords

Cite

@article{arxiv.1606.08868,
  title  = {Highly efficient light-emitting diodes based on intramolecular rotation},
  author = {Dawei Di and Alexander S. Romanov and Le Yang and Saul Jones and Richard H. Friend and Mikko Linnolahti and Manfred Bochmann and Dan Credgington},
  journal= {arXiv preprint arXiv:1606.08868},
  year   = {2018}
}
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