Factors affecting relative stabilities and proton affinities of oxazolidinone and its N,C5-formyl derivatives

Abstract

The proton affinities of all the potential sites of oxazolidinone (OXA) and formyl substituted OXA have been evaluated using ab initio and DFT methods. N4- and C5-formyl oxazolidinone isomers and their protonated structures have been analyzed for relative stabilities. The proton affinity (PA) of carbonyl oxygen of oxazolidinone is observed to be highest in un-substituted and formyl substituted OXA molecules. The PA values decrease for the potential sites in the range 0.5–15.51 kcal/mol as a result of the presence of the formyl substituent. Atomic charges and electron delocalization of neutral and protonated species have been analyzed with the application of NBO. The various factors such as variation in geometrical parameters, atomic charge redistribution, alterations in conjugative interactions, effect of formyl substituent, the presence of intramolecular hydrogen bonding and electronic effects have been explored to rationalize the relative stabilities and proton affinities of OXA and its N,C5 formyl derivatives.