Quantum mechanical methods applied to excitation energy transfer: a comparative analysis on excitation energies and electronic couplings.

We present a comparative study on the influence of the quantum mechanical (QM) method (including basis set) on the evaluation of transition energies, transition densities and dipoles, and excitation energy transfer (EET) electronic couplings for a series of chromophores (and the corresponding pairs) typically found in organic electro-optical devices and photosynthetic systems. On these systems we have applied five different QM levels of description of increasing accuracy (ZINDO, CIS, TD-DFT, CASSCF, and SAC-CI). In addition, we have tested the effects of a surrounding environment (either mimicking a solvent or a protein matrix) on excitation energies, transition dipoles, and electronic couplings through the polarizable continuum model (PCM) description. Overall, the results obtained suggest that the choice of the QM level of theory affects the electronic couplings much less than it affects excitation energies. We conclude that reasonable estimates can be obtained using moderate basis sets and inexpensive methods such as configuration interaction of single excitations or time-dependent density functional theory when appropriately coupled to realistic solvation models such as PCM.

Theoretical study of the 1,3-hydrogen shift of triazene in water.

The 1,3-hydrogen shift of triazene in aqueous solution was studied with a combination of QM/MM methods. First, the different species involved were characterized and the activation free-energies calculated with ASEP/MD, a method that makes use of the mean field approximation. Then the reaction dynamics was simulated with a QM/MM/MD method. A very strong influence of the solvent was observed, both specific, with the participation of a water molecule, and from the rest of the solvent. The effect of solvation on the geometry and electron distribution of triazene is important: N-N bond lengths tend to be more similar and the molecule acquires a planar structure. For the transition state structure, a substantial degree of ionic nature was found. Dynamic solvent effects were also analyzed.

A theoretical study of solvent effects on the 1(n-->pi*) electron transition in acrolein.

The (1)(n-->pi(*)) electron transition of acrolein in liquid water was studied theoretically by using the averaged solvent electrostatic potential/molecular dynamics method. The model combines a multireference perturbational treatment in the description of the solute molecule with molecular dynamics calculations in the description of the solvent. We demonstrate the importance of the solvent electron polarization, bulk solvent effects, and the use of relaxed geometries in solution on the calculated solvent shift. It is also shown that the inclusion of the dynamic correlation does not change the solvent shift although it must be used to reproduce the transition energy.