Issue 1, 2012

Reorganization of perylene bisimide J-aggregates: from delocalized collective to localized individual excitations

Abstract

Water-induced reorganization of individual one-dimensional J-aggregates of perylene bisimide (PBI) dyes was observed by fluorescence microscopy. Fluorescence spectra and decay kinetics of individual J-aggregates immobilized on glass surfaces were measured under a dry nitrogen atmosphere and under humid conditions. The fluorescence properties of PBI J-aggregates arisen from collective excitons under dry nitrogen atmosphere were changed to those of non-interacting dye monomers when water vapor was introduced into the environment (sample chamber). Time-dependent changes of the fluorescence spectra and lifetimes upon exposure to water vapor suggest an initial coordination of water molecules at defect sites leading to the formation of H-type dimer units that act as exciton quenchers, and a subsequent slower disintegration of the hydrogen-bonded J-aggregate into monomers that lack resonance coupling. Our present studies resulted in a direct demonstration of how drastically the optical properties of molecular ensembles and characteristics of their excited states can be changed by delicate reorganization of dye molecules at nanometre scales.

Graphical abstract: Reorganization of perylene bisimide J-aggregates: from delocalized collective to localized individual excitations

Supplementary files

Article information

Article type
Paper
Submitted
29 Jul 2011
Accepted
09 Oct 2011
First published
10 Nov 2011

Nanoscale, 2012,4, 218-223

Reorganization of perylene bisimide J-aggregates: from delocalized collective to localized individual excitations

Y. Tian, V. Stepanenko, T. E. Kaiser, F. Würthner and I. G. Scheblykin, Nanoscale, 2012, 4, 218 DOI: 10.1039/C1NR10973A

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