Your search keyword '"M. Bednarz"' showing total 3 results

1. Low-temperature dynamics of weakly localized Frenkel excitons in disordered linear chains

Author

Jasper Knoester, Victor Malyshev, M. Bednarz, and Theory of Condensed Matter

Subjects

Exciton, Population, FOS: Physical sciences, General Physics and Astronomy, PUMP-PROBE SPECTROSCOPY, NUMERICAL EXPERIMENTS, Molecular physics, 2-EXCITON TRANSITION, LATTICE-VIBRATIONS, PI-CONJUGATED POLYMERS, RADIATIVE LIFETIME, symbols.namesake, Pauli exclusion principle, Stokes shift, Master equation, Radiative transfer, Physical and Theoretical Chemistry, education, Physics, Condensed Matter - Materials Science, education.field_of_study, Materials Science (cond-mat.mtrl-sci), Disordered Systems and Neural Networks (cond-mat.dis-nn), DELOCALIZATION LENGTH, OPTICAL-PROPERTIES, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, ABSORPTION-SPECTRA SIMULATION, SUPERRADIANT EMISSION, symbols, Ground state, Excitation

Abstract

We calculate the temperature dependence of the fluorescence Stokes shift and the fluorescence decay time in linear Frenkel exciton systems resulting from the thermal redistribution of exciton population over the band states. The following factors, relevant to common experimental conditions, are accounted for in our kinetic model: (weak) localization of the exciton states by static disorder, coupling of the localized excitons to vibrations in the host medium, a possible non-equilibrium of the subsystem of localized Frenkel excitons on the time scale of the emission process, and different excitation conditions (resonant or non resonant). A Pauli master equation, with microscopically calculated transition rates, is used to describe the redistribution of the exciton population over the manifold of localized exciton states. We find a counterintuitive non-monotonic temperature dependence of the Stokes shift. In addition, we show that depending on experimental conditions, the observed fluorescence decay time may be determined by vibration-induced intra-band relaxation, rather than radiative relaxation to the ground state. The model considered has relevance to a wide variety of materials, such as linear molecular aggregates, conjugated polymers, and polysilanes., Comment: 15 pages, 8 figures

Published

2004

2. Intraband relaxation and temperature dependence of the fluorescence decay time of one-dimensional Frenkel excitons

Author

M. Bednarz, Jasper Knoester, Victor Malyshev, Zernike Institute for Advanced Materials, Van Swinderen Institute for Particle Physics and G, and Theory of Condensed Matter

Subjects

DYNAMICS, DYE, Phonon, Exciton, Population, LOCALIZATION LENGTH, General Physics and Astronomy, PUMP-PROBE SPECTROSCOPY, RADIATIVE LIFETIME, symbols.namesake, Pauli exclusion principle, Master equation, Radiative transfer, SCATTERING, Spontaneous emission, Physical and Theoretical Chemistry, education, PHOTOSYNTHETIC ANTENNA COMPLEXES, Biexciton, Physics, education.field_of_study, Condensed matter physics, SUPERRADIANT EMISSION, symbols, Atomic physics, ENERGY-TRANSFER

Abstract

In molecular J-aggregates one often observes an increase of the fluorescence decay time when increasing the temperature from 0 K. This phenomenon is usually attributed to the thermal population of the dark Frenkel exciton states that lie above the superradiant bottom state of the exciton band. In this paper, we study this effect for a homogeneous one-dimensional aggregate in a host medium and we model the scattering between different exciton states as arising from their coupling to the host vibrations. A Pauli master equation is used to describe the redistribution of excitons over the band. The rates entering this equation are calculated within the framework of first-order perturbation theory, assuming a linear on-site interaction between excitons and acoustic phonons. Solving the master equation numerically for aggregates of up to 100 molecules, we calculate the temperature dependence of the fluorescence kinetics in general and the decay time scale in particular. The proper definition of the fluorescence decay time is discussed in detail. We demonstrate that, even at a quantum yield of unity, the possibility to directly interpret fluorescence experiments in terms of a simple radiative time scale depends crucially on the initial excitation conditions in combination with the competition between spontaneous emission and intraband phonon-assisted relaxation.

Published

2002

3. Low-temperature dynamics of weakly localized Frenkel excitons in disordered linear chains.

Author

Bednarz M, Malyshev VA, and Knoester J

Abstract

We calculate the temperature dependence of the fluorescence Stokes shift and the fluorescence decay time in linear Frenkel exciton systems resulting from the thermal redistribution of exciton population over the band states. The following factors, relevant to common experimental conditions, are accounted for in our kinetic model: (weak) localization of the exciton states by static disorder, coupling of the localized excitons to vibrations in the host medium, a possible nonequilibrium of the subsystem of localized Frenkel excitons on the time scale of the emission process, and different excitation conditions (resonant or nonresonant). A Pauli master equation, with microscopically calculated transition rates, is used to describe the redistribution of the exciton population over the manifold of localized exciton states. We find a counterintuitive nonmonotonic temperature dependence of the Stokes shift. In addition, we show that depending on experimental conditions, the observed fluorescence decay time may be determined by vibration-induced intraband relaxation, rather than radiative relaxation to the ground state. The model considered has relevance to a wide variety of materials, such as linear molecular aggregates, conjugated polymers, and polysilanes., ((c) 2004 American Institute of Physics.)

Published

2004