The torsional barriers of 2'-substituted 2-arylpyridines have been probed experimentally (by using dynamic NMR spectroscopy) and computationally (by using density functional theory). Due to the compressibility of the lone pair, the torsional barriers of the arylpyridines are up to 4.2 kcal/mol smaller than those of the carba-analogous biphenyls. Furthermore, the ground states of the 2-arylpyridines are less twisted than those of the biphenyls. Finally, due to an out-ofcollinearity distortion, the intramolecular repulsion is attenuated in both rotational transition states, in the syn coplanar conformer (in which the pyridine nitrogen and the substituent R face each other) and in the anti coplanar conformer (in which they are on opposite sides of the molecule
A. Mazzanti, L. Lunazzi, S. Lepri, R. Ruzziconi, M. Schlosser (2011). How Space-Filling Is a Pyridine Lone Pair?. EUROPEAN JOURNAL OF ORGANIC CHEMISTRY, nd, 6725-6731 [10.1002/ejoc.201101008].
How Space-Filling Is a Pyridine Lone Pair?
MAZZANTI, ANDREA;LUNAZZI, LODOVICO;
2011
Abstract
The torsional barriers of 2'-substituted 2-arylpyridines have been probed experimentally (by using dynamic NMR spectroscopy) and computationally (by using density functional theory). Due to the compressibility of the lone pair, the torsional barriers of the arylpyridines are up to 4.2 kcal/mol smaller than those of the carba-analogous biphenyls. Furthermore, the ground states of the 2-arylpyridines are less twisted than those of the biphenyls. Finally, due to an out-ofcollinearity distortion, the intramolecular repulsion is attenuated in both rotational transition states, in the syn coplanar conformer (in which the pyridine nitrogen and the substituent R face each other) and in the anti coplanar conformer (in which they are on opposite sides of the moleculeI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
