Investigation of atomic multipolos from quantum theory of atoms in molecules in study of molecular properties

The charges, dipoles, quadrupoles and high order terms, along with their derivatives, allow a better understanding of electric properties. We can cite dipole moments, dipole moment derivatives, infrared intensities, electrostatic potentials and electrostatic forces. The multipoles treated here are obtained from the Quantum Theory of Atoms in molecules (QTAIM) and they are compared with CHELPG (CHarges from Electrostatic Potentials using a Grid based method) results. The investigations of this project can be divided in two distinct parts and the first one focuses in the performance of atomic multipoles in the description of electrostatic potentials when one positive particle interacts with molecules. Some simple diatomic (F2 , Cl2 , BF, AlF, BeO, MgO, LiH and NaCl) and polyatomic molecules (H2O, H2CO, NH3 ,PH3 ,BF3 and CO2) were considered in this investigation and the calculations were carried out at the B3LYP/6-311G(3d,3p) level. The second part of this dissertation was a study of infrared intensities in vibrational modes by means of the charge-charge flux -dipole flux model. The systems treated now are dimers with hydrogen bonds such as homodimers (H2O-H2O, HF-HF, HCl-HCl, HCN-HCN, HNC-HNC and NH3-NH3) and heterodimers (HF-HCN, HCl-HF and HF-H2O). The calculations of these systems were carried out at the CCSD/cc-pVQZ-mod level. The results suggest that QTAIM multipoles are better in describing electrostatic potentials in almost all proton-molecule arrangements than CHELPG charges. The charge-charge flux -dipole flux model can reproduce infrared intensities of dimer with hydrogen bonds. Finally, the increase in intensities of X-H stretching modes associated to the donor monomer in linear dimers is explained by changes in charge flux contributions during dimerization. (AU)