Excitonic Funneling in Extended Dendrimers with Non-Linear and Random
  Potentials

A. Bar-Haim; A. Bar-Haim; A. Bar-Haim; A. Bar-Haim; B. Derrida; B. Derrida; C. Devadoss; C. W. Rella; D. A. Tomalia; D.-L. Jiang; H. P. Lu; J. Frechet; J. P. Bouchaud; K. P. N. Murthy; M. Pope; M. R. Shortreed; M. Shortreed; R. Kopelman; S. H. Noskowicz; S. Tretiak; S. Tretiak; Shaul Mukamel; Subhadip Raychaudhuri; T. Pullerits; V. Blazani; Vladimir Chernyak; Y. Y. Goldschmidt; Ya. G. Sinai; Yonathan Shapir

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Excitonic Funneling in Extended Dendrimers with Non-Linear and Random Potentials

Authors: A. Bar-Haim
A. Bar-Haim
A. Bar-Haim
A. Bar-Haim
B. Derrida
B. Derrida
C. Devadoss
C. W. Rella
D. A. Tomalia
D.-L. Jiang
H. P. Lu
J. Frechet
J. P. Bouchaud
K. P. N. Murthy
M. Pope
M. R. Shortreed
M. Shortreed
R. Kopelman
S. H. Noskowicz
S. Tretiak
S. Tretiak
Shaul Mukamel
Subhadip Raychaudhuri
T. Pullerits
V. Blazani
Vladimir Chernyak
Y. Y. Goldschmidt
Ya. G. Sinai
Yonathan Shapir
Publication date: 28 June 2000
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The mean first passage time (MFPT) for photoexcitations diffusion in a funneling potential of artificial tree-like light-harvesting antennae (phenylacetylene dendrimers with generation-dependent segment lengths) is computed. Effects of the non-linearity of the realistic funneling potential and slow random solvent fluctuations considerably slow down the center-bound diffusion beyond a temperature-dependent optimal size. Diffusion on a disordered Cayley tree with a linear potential is investigated analytically. At low temperatures we predict a phase in which the MFPT is dominated by a few paths.Comment: 4 pages, 4 figures, To be published in Phys. Rev. Let

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