Origin of spectral broadening in pi-conjugated amorphous semiconductors

J M Lupton, I D W Samuel, P L Burn

Research output: Contribution to journalArticlepeer-review

14 Citations (Scopus)

Abstract

We present a study of the picosecond fluorescence dynamics of pi-conjugated semiconducting organic dendrimers in the solid state. By varying the degree of branching within the dendrons, referred to as the dendrimer generation, a control of intermolecular spacing of the emissive core and therefore of the lattice parameter for Forster-type energy transfer is achieved. This allows a distinction between spectral diffusion and excimer formation as the two main sources of spectral broadening in organic semiconductors. Whereas Forster-type dispersive spectral relaxation is independent of temperature but strongly dependent on the interchromophore distance, excimer formation is also strongly thermally activated due to temperature-dependent conformational changes and the influence of thermally activated dynamic disorder. The rapid spectral diffusion allows a determination of the excimer rise in the emission, which is shown to have a profound impact on the steady state luminescence properties of dendrimer films. We show that the dendrimer generation not only allows a microscopic control of intermolecular interactions but also a direct control of the rate of spectral diffusion. Implications for the design of novel materials for optoelectronic devices are discussed.

Original languageEnglish
Article number155206
Number of pages6
JournalPhysical Review. B, Condensed matter and materials physics
Volume66
Issue number15
DOIs
Publication statusPublished - 15 Oct 2002

Keywords

  • MONTE-CARLO SIMULATIONS
  • FLUORESCENCE DYNAMICS
  • DENDRIMER GENERATION
  • RELAXATION DYNAMICS
  • POLYFLUORENE FILM
  • POLYMERS
  • PHOTOLUMINESCENCE
  • PHOTOEXCITATIONS
  • LUMINESCENCE
  • EXCITATIONS

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