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Doubly Encapsulated Perylene Diimides: Effect of Molecular Encapsulation on Photophysical Properties.

Jeroen RoyakkersAlessandro MinottoDaniel G CongraveWeixuan ZengAdil PatelAndrew D BondDejan-Krešimir BučarFranco CacialliHugo Bronstein
Published in: The Journal of organic chemistry (2019)
Intermolecular interactions play a fundamental role on the performance of conjugated materials in organic electronic devices, as they heavily influence their optoelectronic properties. Synthetic control over the solid state properties of organic optoelectronic materials is crucial to access real life applications. Perylene diimides (PDIs) are one of the most highly studied classes of organic fluorescent dyes. In the solid state, π-π stacking suppresses their emission, limiting their use in a variety of applications. Here, we report the synthesis of a novel PDI dye that is encapsulated by four alkylene straps. X-ray crystallography indicates that intermolecular π-π stacking is completely suppressed in the crystalline state. This is further validated by the photophysical properties of the dye in both solution and solid state and supported by theoretical calculations. However, we find that the introduction of the encapsulating "arms" results in the creation of charge-transfer states which modify the excited state properties. This article demonstrates that molecular encapsulation can be used as a powerful tool to tune intermolecular interactions and thereby gain an extra level of control over the solid state properties of organic optoelectronic materials.
Keyphrases
  • solid state
  • water soluble
  • signaling pathway
  • photodynamic therapy
  • magnetic resonance imaging
  • molecular dynamics simulations
  • quantum dots
  • density functional theory
  • energy transfer
  • ionic liquid