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 language | English |
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Article number | 155206 |
Number of pages | 6 |
Journal | Physical Review. B, Condensed matter and materials physics |
Volume | 66 |
Issue number | 15 |
DOIs | |
Publication status | Published - 15 Oct 2002 |
Keywords
- MONTE-CARLO SIMULATIONS
- FLUORESCENCE DYNAMICS
- DENDRIMER GENERATION
- RELAXATION DYNAMICS
- POLYFLUORENE FILM
- POLYMERS
- PHOTOLUMINESCENCE
- PHOTOEXCITATIONS
- LUMINESCENCE
- EXCITATIONS