Ch. Warmuth scite author profile

Photoexcitations coupled to intrachain, backbone modes of a flexible π-conjugated polyarylene polymer and their effect on the relaxational dynamics of migrative excitation transfer have been examined by using femtosecond and picosecond time resolved fluorescence techniques. In poly[4,4‘-diphenylene-1,2-di(3,4-dimethoxyphenyl)vinylene], DMOP-PDPV, a vertical excitation into the biphenylic segmental unit is subject to a quasi-instantaneous torsional, energetic relaxation that gives rise to large bathochromic shift of the gated fluorescence spectrum on time scales < 200 fs. For times > 200 fs the (new-equilibrium) excited-state population evolves in the subsequent, electronic excitation energy transfer process (EET), but the rates in the ongoing, dissipative energy relaxation (up to several tens of nanoseconds!) are relatively slow and significantly delayed as compared to those in the more rigid poly(phenylenevinylene), PPV. The results are interpreted in terms of factored time scales for nuclear motion and electronic hopping modes. The significant slowing of the EET is related to the reduced Förster spectroscopic overlap integral, as a result of the sudden (<200 fs), large Stokes shift between vertical and structurally relaxed excitations. The energy shift of fluorescence photons in the course of EET, comparatively smaller than that brought about by the nuclear relaxation process and, due to the deceleration of EET, even still detectable on a nanosecond scale, can be understood as the result of a dissipative relaxation along a site energy cascade. The latter energy-dispersive pathway stems from a density of states (DOS) of localized S1-states whose incoherent electronic communication can be adequately described within the framework of a molecular, excitonic picture in the limit of incoherent, non-Markovian motion.

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Femtosecond excitation tuning and site energy memory of population transfer in poly(p-phenylenevinylene): Gated luminescence experiments and simulation

Sperling

Milota

Tortschanoff

et al. 2002

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We present a comprehensive experimental and computational study on fs-relaxational dynamics of optical excitations in the conjugated polymer poly(p-phenylenevinylene) (PPV) under selective excitation tuning conditions into the long-wavelength, low-vibrational S1ν=0-density-of-states (DOS). The dependence of single-wavelength luminescence kinetics and time-windowed spectral transients on distinct, initial excitation boundaries at 1.4 K and at room temperature was measured applying the luminescence up-conversion technique. The typical energy-dispersive intra-DOS energy transfer was simulated by a combination of static Monte Carlo method with a dynamical algorithm for solving the energy-space transport Master-Equation in population-space. For various, selective excitations that give rise to specific S1-population distributions in distinct spatial and energetic subspaces inside the DOS, simulations confirm the experimental results and show that the subsequent, energy-dissipative, multilevel relaxation is hierarchically constrained, and reveals a pronounced site-energy memory effect with a migration-threshold, characteristic of the (dressed) excitation dynamics in the disordered PPV many-body system.

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Excitonic fs-luminescence rise in poly(phenylenevinylene), PPV

Warmuth

Tortschanoff

Brunner

et al. 1998

Journal of Luminescence

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Advanced methods for the characterization of few-cycle light pulses: a comparison

et al. 2006

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Ultrafast optical dynamics of spiro-compounds

Milota¹,

Warmuth²,

Tortschanoff³

et al. 2001

Synthetic Metals

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Ch. Warmuth

Site Torsional Motion and Dispersive Excitation Hopping Transfer in π-Conjugated Polymers

Femtosecond excitation tuning and site energy memory of population transfer in poly(p-phenylenevinylene): Gated luminescence experiments and simulation

Excitonic fs-luminescence rise in poly(phenylenevinylene), PPV

Advanced methods for the characterization of few-cycle light pulses: a comparison

Ultrafast optical dynamics of spiro-compounds

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