Interaction of formamide with water.

The amide group is found in biomolecules such as proteins, nucleic acids, as well as synthetic polymers. The simplest molecule that contains the amide group is formamide. A large number of studies have been made on vacuum, liquid state and on various solvents, using the most different computational and experimental techniques, but there are many fundamental questions to be answered about its electronic structure and solvation. The precise knowledge about resonance and conformational barriers of this compound is of fundamental importance for the understanding of conformational behavior of biomolecules and synthetic polymers. A detailed understanding about the interactions of this molecule with water is equally important, for the amide group is one of the major sites of solvation in proteins. This work has the objective of studying the interactions of formamide and water, on the minimum energy conformation and the transition conformations of the amide group and the electronic structure of formamide. It has been found the existence of great differences between the electronic structure of formamide on its more stable conformation and the conformational transition states of the amide group rotation. Using the Natural Bond Orbital (NBO) analysis, a decrease of resonance effects on the transitions states was verified, due to the loss of interaction between the electrons of the nitrogen lone pair and the carbonyl 'pi' anti-bonding orbital (nN→'pi'*CO). The solvation of formamide has changed the electronic structure of planar formamide and the conformational transition states. The intermolecular interactions between planar formamide and water are very strong, specially when the solvent molecules interact simultaneously with the carbonyl and amide groups. Regarding the conformational transition states, the interaction between the nitrogen lone pairs of amide and the water molecule is observed. The hydrogen bond energies of formamide and water stabilizes the supermolecules. It can be verified that there is cooperativity only with energies and not in other properties. Using the NBO and the Natural Resonance Theory (NRT) methods, an increase of resonance for the planar form with the successive addition of water molecules has been verified. This observation suggests that the hydrogen bonds between formamide and water have some covalent character. The solvation study of formamide using the discrete/continuous model shows that the explicit waters influence the free energy of solvation. A preference for the solvation of carbonyl oxygen and the validity of the discret/continuous model has been verified. (AU)