RESUMO
In this paper we report the synthesis of two new complexes, [Eu(fod)(3)(phen)] and [Tb(fod)(3)(phen)] (fod = 6,6,7,7,8,8,8-heptafluoro-2,2-dimethyl-3,5-octadionate and phen = 1,10-phenanthroline), and their complete characterization, including single-crystal X-ray diffraction, UV-vis spectroscopy, IR spectroscopy, and TGA. The complexes were studied in detail via both theoretical and experimental approaches to the photophysical properties. The [Eu(fod)(3)(phen)] complex crystallizes in the monoclinic space group P2(1)/c. The crystal structure of [Eu(fod)(3)(phen)] exhibits an offset pi-pi stacking interaction between the phenanthroline ligands of adjacent lanthanide complexes. The Eu(3+) cation is coordinated to three fod anionic ligands and to one phen. The symmetry around Eu(3+) is best described as a highly distorted square antiprism. The molar absorption coefficients of [Eu(fod)(3)(phen)] and [Tb(fod)(3)(phen)] revealed an improved ability to absorb light in comparison with the stand-alone phen and fod molecules. [Tb(fod)(3)(phen)] emits weak UV excitation, with this feature being explained by the triplet-(5)D(4) resonance, which contributes significantly to the nonradiative deactivation of Tb(3+), causing a short lifetime and low quantum yield. The intensity parameters (Omega(2), Omega(4), and Omega(6)) of [Eu(fod)(3)(phen)] were calculated for the X-ray and Sparkle/AM1 structures and compared with values obtained for [Eu(fod)(3)(H(2)O)(2)] and [Eu(fod)(3)(phen-N-O)] (phen-N-O = 1,10-phenanthroline N-oxide) samples. Intensity parameters were used to predict the radiative decay rate. The theoretical quantum efficiencies from the X-ray and Sparkle/AM1 structures are in good agreement with the experimental values, clearly attesting to the efficacy of the theoretical models.
RESUMO
This work describes a rational planning of a new light-conversion molecular device with high quantum yield. For this, we made modifications in the 3-amino-2-carboxypyridine and 3-amino-2-carboxypirazine acid ligands, generating eight different complexes. Theoretical methods have been used to calculate the quantum yield of each of the complexes. We first used the Sparkle model to calculate the ground-state geometries of the eight complexes. These data were used to perform theoretical predictions of the energy transitions using the INDO/S-CI method. After having obtained the geometry and the energy transitions, the energy transfer rates and quantum yield were calculated using a theoretical approach based on the application of the 4f-4f transition theory. The results show that the modifications in the 3-amino-2-carboxypyridine ligand had generated three complexes with high quantum yield (about 52.8, 51.6 and 52.8%). On the other hand, the modifications in the 3-amino-2-carboxypirazine led to only one complex with quantum yield larger than 50%, but it is the most efficient complex projected.