Femtosecond time-resolved experiments demonstrate that the photoexcited state of perylene tetracarboxylic acid bisimide (PBI) aggregates in solution decays nonradiatively on a time-scale of 215 fs. High-level electronic structure calculations on dimers point toward the importance of an excited state intermolecular geometry distortion along a reaction coordinate that induces energy shifts and couplings between various electronic states. Time-dependent wave packet calculations incorporating a simple dissipation mechanism indicate that the fast energy quenching results from a doorway state with a charge-transfer character that is only transiently populated. The identified relaxation mechanism corresponds to a possible exciton trap in molecular materials.
The exciton diffusion length (LD) is a key parameter for the efficiency of organic optoelectronic devices. Its limitation to the nm length scale causes the need of complex bulk-heterojunction solar cells incorporating difficulties in long-term stability and reproducibility. A comprehensive model providing an atomistic understanding of processes that limit exciton trasport is therefore highly desirable and will be proposed here for perylene-based materials. Our model is based on simulations with a hybrid approach which combines high-level ab initio computations for the part of the system directly involved in the described processes with a force field to include environmental effects. The adequacy of the model is shown by detailed comparison with available experimental results. The model indicates that the short exciton diffusion lengths of α-perylene tetracarboxylicdianhydride (PTCDA) are due to ultrafast relaxation processes of the optical excitation via intermolecular motions leading to a state from which further exciton diffusion is hampered. As the efficiency of this mechanism depends strongly on molecular arrangement and environment, the model explains the strong dependence of LD on the morphology of the materials, for example, the differences between α-PTCDA and diindenoperylene. Our findings indicate how relaxation processes can be diminished in perylene-based materials. This model can be generalized to other organic compounds.
Ocean acidification caused by anthropogenic uptake of CO2 is perceived to be a major threat to calcifying organisms. Cold-water corals were thought to be strongly affected by a decrease in ocean pH due to their abundance in deep and cold waters which, in contrast to tropical coral reef waters, will soon become corrosive to calcium carbonate. Calcification rates of two Mediterranean cold-water coral species, Lophelia pertusa and Madrepora oculata, were measured under variable partial pressure of CO2 (pCO2) that ranged between 380 µatm for present-day conditions and 930 µatm for the end of the century. The present study addressed both short- and long-term responses by repeatedly determining calcification rates on the same specimens over a period of 9 months. Besides studying the direct, short-term response to elevated pCO2 levels, the study aimed to elucidate the potential for acclimation of calcification of cold-water corals to ocean acidification. Net calcification of both species was unaffected by the levels of pCO2 investigated and revealed no short-term shock and, therefore, no long-term acclimation in calcification to changes in the carbonate chemistry. There was an effect of time during repeated experiments with increasing net calcification rates for both species, however, as this pattern was found in all treatments, there is no indication that acclimation of calcification to ocean acidification occurred. The use of controls (initial and ambient net calcification rates) indicated that this increase was not caused by acclimation in calcification response to higher pCO2. An extrapolation of these data suggests that calcification of these two cold-water corals will not be affected by the pCO2 level projected at the end of the century.
We present a modified approach for simulating electronically nonadiabatic dynamics based on the Nakajima-Zwanzig generalized quantum master equation (GQME). The modified approach utilizes the fact that the Nakajima-Zwanzig formalism does not require casting the overall Hamiltonian in system-bath form, which is arguably neither natural nor convenient in the case of the Hamiltonian that governs nonadiabatic dynamics. Within the modified approach, the effect of the nuclear degrees of freedom on the time evolution of the electronic reduced density operator is fully captured by a memory kernel super-operator. A methodology for calculating the memory kernel from projection-free inputs is developed. Simulating the electronic dynamics via the modified approach, with a memory kernel obtained using exact or approximate methods, can be more cost effective and/or lead to more accurate results than direct application of those methods. The modified approach is compared to previously proposed GQME-based approaches, and its robustness and accuracy are demonstrated on a benchmark spin-boson model with a memory kernel which is calculated within the Ehrenfest method.
Using polarized 2D spectroscopy and state-of-the-art TDDFT calculations to uncover the vibronic structure of primary photosynthetic pigments and its effect on ultrafast photoexcited dynamics.
Cu(I) 4H-imidazolato complexes are excellent
photosensitizers with broad and intense light absorption properties,
based on an earth-abundant metal, and hold great promise as photosensitizers
in artificial photosynthesis and for accumulation of redox equivalents.
In this study, the excited-state relaxation dynamics of three novel
heteroleptic Cu(I) 4H-imidazolato complexes
with phenyl, tolyl, and mesityl side groups are systematically investigated
by femtosecond and nanosecond time-resolved transient absorption spectroscopy
and theoretical methods, complemented by steady-state absorption spectroscopy
and (spectro)electrochemistry. After photoexcitation into the metal-to-ligand
charge transfer (MLCT) and intraligand charge transfer absorption
band, fast (0.6–1 ps) intersystem crossing occurs into
the triplet MLCT manifold. The triplet-state population relaxes via the geometrical planarization of the N-aryl rings on the Cu(I) 4H-imidazolato complexes.
Depending on the initial Franck–Condon state, the remaining
small singlet state population relaxes into two geometrically distinct
minima geometries with similar energy, S1/2,relax and S3/4,relax. Subsequent ground-state recovery from S1/2,relax and internal conversion from S3/4,relax to S1/2,relax take place on a 100 ps time scale. The internal conversion
can be understood as hole transfer from a dyz-orbital to
a dxz-orbital, which is accompanied with the structural
reorganization of the coordination environment. Generally, the photophysical
processes are determined by the steric hindrance of the side groups
on the ligands. And the excited singlet-state pathways are dependent
on the excitation wavelength.
Spectral peaks of the special pair
(P) and adjacent pigments in
the bacterial reaction center (BRC) are investigated computationally.
We employ a novel framework based on a polarization-consistent treatment
of the dielectric environment, combining the polarizable continuum
model (PCM) with time-dependent screened range-separated hybrid (SRSH)
density functional theory. Our calculations quantitatively reproduce
recently measured spectral peak splits between P excitonic states
and spectral asymmetries within the pairs of excited states of the
adjacent bacteriochlorophyll a (BChl) and bacteriopheophytin a (BPhe) pigments. For the special pair, a splitting energy
between the absorptive state and a blue-shifted semidark state of
0.07 eV is found in close agreement with the measured value. The spectral
asymmetries within the pseudosymmetric pairs of BChl and BPhe pigments
are interpreted to result from locally different effective dielectric
environments in the A and the B branch, where the latter are exposed
to a lesser polarizing environment. We base our analysis on X-ray-resolved
structures and where the effect of neighboring pigments on the electronic
structure is addressed through an effective dielectric environment.
We show that the spectral trends are only reproduced using a polarization-consistent
framework based on a screened range-separated hybrid functional, whereas
B3LYP-PCM energies fail to provide the correct trends.
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