Theoretical study of the substituent effect on the intramolecular hydrogen bonds in di(4‐hydroxycoumarin) derivatives

Geometry optimization of ortho ‐, meta ‐, and para ‐pyridyl‐substituted di(4‐hydroxycoumarin) [di(4‐HC)] was performed with the density functional theory (DFT) [B3LYP/6‐31G( d )] method. Two asymmetrical intramolecular OH…O hydrogen bonds (HBs) stabilized the structures. The calculated single HB energies varied from −62.56 to −47.53 kJ mol −1 and pointed to a relative strong hydrogen bond in the systems studied. The 2‐ and 6‐pyridyl substituents produced the largest geometrical changes in di(4‐hydroxycoumarin) fragment. The highest total HB energy was found for 2‐pyridyl‐substituted and the lowest one for 6‐pyridyl‐substituted di(4‐hydroxycoumarin). The HB energy variations were confirmed with rotational barrier method calculations. Both steric and electrostatic factors were found to be responsible for the HB asymmetry in the compounds studied. According to the molecular electrostatic potential (MEP) calculations the most preferred reactive site for electrophilic attack of pyridyl‐substituted di(4‐hydroxycoumarin)s are the pyridine nitrogen and the carbonyl oxygens, followed by the hydroxyl oxygens. © 2005 Wiley Periodicals, Inc. Int J Quantum Chem, 2006