Your search keyword '"van Dijk EM"' showing total 2 results

1. Power-law blinking in the fluorescence of single organic molecules.

Author

Hoogenboom JP, Hernando J, van Dijk EM, van Hulst NF, and García-Parajó MF

Subjects

Fluorescent Dyes chemistry, Imides chemistry, Models, Molecular, Models, Statistical, Molecular Structure, Perylene analysis, Perylene chemistry, Photons, Rhodamines chemistry, Spectrometry, Fluorescence statistics & numerical data, Statistical Distributions, Time Factors, Fluorescent Dyes analysis, Imides analysis, Perylene analogs & derivatives, Spectrometry, Fluorescence methods

Abstract

The blinking behavior of perylene diïmide molecules is investigated at the single-molecule level. We observe long-time scale blinking of individual multi-chromophoric complexes embedded in a poly(methylmethacrylate) matrix, as well as for the monomeric dye absorbed on a glass substrate at ambient conditions. In both these different systems, the blinking of single molecules is found to obey analogous power-law statistics for both the on and off periods. The observed range for single-molecular power-law blinking extends over the full experimental time window, covering four orders of magnitude in time and six orders of magnitude in probability density. From molecule to molecule, we observe a large spread in off-time power-law exponents. The distributions of off-exponents in both systems are markedly different whereas both on-exponent distributions appear similar. Our results are consistent with models that ascribe the power-law behavior to charge separation and (environment-dependent) recombination by electron tunneling to a dynamic distribution of charge acceptors. As a consequence of power-law statistics, single molecule properties like the total number of emitted photons display non-ergodicity.

Published

2007

2. Synthesis and characterization of long perylenediimide polymer fibers: from bulk to the single-molecule level.

Author

De Witte PA, Hernando J, Neuteboom EE, van Dijk EM, Meskers SC, Janssen RA, van Hulst NF, Nolte RJ, García-Parajó MF, and Rowan AE

Subjects

Anisotropy, Circular Dichroism, Indicators and Reagents, Microscopy, Atomic Force, Microscopy, Confocal, Nanowires, Perylene chemical synthesis, Spectrometry, Fluorescence, Spectrophotometry, Infrared, Temperature, Imides chemical synthesis, Perylene analogs & derivatives

Abstract

The synthesis and characterization of perylenediimide polyisocyanides is reported. In addition to short oligomers, our synthetic approach results in the formation of extremely long, well-defined, and rigid perylenediimide polymers. Ordering and close-packing of the chromophores in these long polymers is guaranteed by attachment to a polyisocyanide backbone with amino acid side chains. Hydrogen bonding interactions between those groups stabilize and rigidify the helical polymer structure. The rodlike nature of the synthesized long perylenediimide pendant polyisocyanides as well as the helical arrangement of the chromophores is demonstrated by means of atomic force microscopy. Remarkably, polymer fibers up to 1 mum in length have been visualized, containing several thousands of perylenediimide molecules. Circular dichroism spectroscopy reveals the chiral organization of the chromophore units in the polymer, whereas absorption and emission measurements prove the occurrence of excited-state interactions between those moieties due to the close packing of the chromophore groups. However, an intricate optical behavior is encountered in bulk as a result of the coexistence of short oligomers and long polymers of perylenediimide, a situation subsequently uncovered by means of single-molecule experiments. Individual long helical perylenediimide polyisocyanides exhibit a typical red-shifted fluorescence spectrum, which, together with depolarized emission continuously decreasing in time, demonstrate that fluorescence arises from multiple excimer-like species in the polymer. Upon continuous irradiation of these long polymers, a fast decay in fluorescence lifetime is observed, a situation explained by photoinduced creation of quenching sites. Radical/ion formation by intramolecular electron transfer between close-by perylenediimide moieties is the most probable mechanism for this process. Appropriate control of the electron-transfer process might open the possibility of applying these polymers as perylenediimide-based supramolecular nanowires.

Published

2006