Studies of Solvent Effects in the Electronic Absorption Spectrum of the Brooker\'s merocyanine and Derivatives.

In this thesis we studied the absorption spectrum of merocyanine Brooker (MB) and three derivatives in solvents with different polarities.The interest in this system is given by the presence of some particular properties of this molecule, for example, it presents a large solvatochromic shift due to the change in the polarity of the medium. We present the results for the absorption spectrum of the molecules considering different structures to the ground state: forms trans, cis, zwitterionic (zw), protonated MBH+ and dimer (MB2). The solvent effect was treaty by different ways: (i) continuous model using the PCM polarizable, (ii) by an average electrostatic configuration of solvent, ASEC, (iii) including some explicit solvent molecules with an electrostatic environment generated by other solvent molecules. As an additional investigation, we present results of experimental measurements in the thesis. We have seen, through quantum calculations, that the forms cis/trans have the electronic excitation in the same region and the structural deformation generated in the zw form causes a red shift. Our theoretical and experimental results show that the MBH+ form has a small solvatochromism, with displacement of 20 nm caused by water-chloroform change. Performing spectroscopic titration we got the pKa associated with the process of deprotonation/protonation of MB in water and methanol. In water we obtained a value of 8.7, in good agreement with the values reported in the literature. We present a unpublished pKap for the MB in methanol, 9.9. We got a good theoretical description for electronic excitation of MB in solvents with high polarity, in the region between 430-500 nm, using a method quantum TD-DFT B3LYP and CAM-B3LYP functional whit basic functions set 6-311+G** but the excitation in low polarity solvents, which occurs in the region between 550-650 nm, is not properly described considering the MB form in the solvents. We have seen, through experimental studies that the MB probe can aggregate in low polarity solvents. Theoretical calculations for dimer in solution showed the existence of a low intensity electron excitation in this region. Additionally, the experimental spectra in low polarity solvents showed 2 bands, where in the second band is similar to the observed to MBH+ form. To explain these two experimental bands for MB, we present a theoretical proposal where there is a proton transfer (H+) between the monomers of the dimer, generating a deprotonated structure (MBH-) and a protonated (MBH+). Theoretical calculations for the MBH- show that this form presents an electronic excitation of moderate intensity in the region between 550-650 nm. With this assumption we can describe, through theoretical calculations, the anomalous solvatochromism for the electronic absorption spectrum of MB in the two polarity regions of solvents: high polarity is described by the MB form, and low polarity, described by the MBH- form. (AU)