Hydrogen bonds and substituent effect - Influence in the resonance and aromaticity of the cations and organic acids

The nature of hydrogen bonds and their influence on electronic structure of neutral, cationic, anionic, and radical complexes was studied by using geometric, energetic, electronic, and topological analysis. The changes in aromaticity of the pyrylium cation upon complexation with one up to three water molecules were investigated. The PCM (Polarizable Continuum Model) model was employed to study the pyrylium-water complexes in a water reaction medium. In addition, the effects of hydroxylation on electronic structure of the benzopyrylium and flavilium cations were also considered. In addition, the effects of strong hydrogen bonds on carboxyl group resonance in the complexes formed between the hydroperoxyl radical and formic, acetic, and trifluoroacetic acids were analyzed. In extension of this work, studies including complexes, obtained with and without geometric restrictions, provided information about the resonance of the carboxyl and carboxylate groups when the hydrogen fluoride interacts, linear or perpendicularly, with all atoms of formic acid and formate anion. The analysis of the wavefunction by using NBO (Natural Bond Orbital), NSA (Natural Steric Analysis), NRT (Natural Resonance Theory), and AIM (Atoms in Molecules) methods was necessary to the development of the above mentioned activities. The changes in geometric parameters and atomic charges were also considered. An energetic analysis of complexes was done with the energy decomposition method proposed by Xantheas. The vibrational frequencies and the intensity of the X-H (hydrogen bond donor group) stretching bands were studied. The spin densities for the radical complexes were also obtained. The Nucleus Independent Chemical Shifts (NICS), Harmonic Oscillator Model of Aromaticity (HOMA), HOSE (Harmonic Oscillator Stabilization Energy), and PDI (para-Delocalization Index) aromaticity criteria were employed to verify the hydrogen bond influence and the effect of hydroxylation in the aromaticity of the cations. The calculations were carried out by using B3LYP/6-31+G(d,p), B3LYP/6-311++G(3df,3pd), and UB3LYP/6-311++G(3df,3pd) models. Occasionally, other basis set (EPR-III and cc-pVDZ), as well as the MP2 method, were applied to test the accuracy of the results. The intermolecular interactions lead to small alterations in the electronic structure and aromaticity of pyrylium cation. Similarly, the substitution at different positions of the benzopyrylium and flavilium cations by a hydroxyl group does not cause significant changes in the electronic structure of these cations. However, a dependence of the hydroxyl group position on aromaticity was observed. On the other hand, for formic, acetic, trifluoroacetic acids, as well as for the formate anion, the resonance of the carboxyl and carboxylate groups is affected not only by the geometric distortions but also by the hydrogen bonds. The effects of the electron-donating and electron-withdrawing groups in the stabilization of radical complexes were characterized. Furthermore, a partial covalent character can be attributed to some hydrogen bonds. (AU)