Anomeric effect rotational barriers

Lemieux, R. U., and S. Koto The Conformational Properties of Glycosidic Linkages. Tetrahedron 30, 1933 (1974) Bailey, W. F., and E. L. Eliel Conformational Analysis. XXIX. 2-Substituted and 2,2-Disubstituted 1,3-Dioxanes. The Generalized and Reverse Anomeric Effects. J. Amer. Chem. Soc. 96, 1798 (1974) Anet, F. A. L., and I. Yavari Generalized Anomeric Effect and Barrier to Internal Rotation about the Oxygen-Methylene Bond in Chloromethyl Ether. J. Amer. Chem. Soc. 99, 6752 (1977). 

In comparison with previous plots of this section, the no-crco anomeric interaction of Fig. 3.65 can be seen to be a rather typical example of hyperconjugative donor-acceptor interactions. Consequently, there seems to be no valid reason to invoke a special effect for the conformational preferences of sugars, obscuring their essential conformity with a unified donor-acceptor picture of ethane-like rotation barriers. 

These results clearly indicate that barriers to all isomerisation processes are at least less than about 8kcalmol 1. In /V-benzyloxy-7V-chlorobenzamide 44 the amide isomerisation was not observable but the anomeric overlap resulted in diastereotopic benzylic hydrogens, which at coalescence afforded a barrier for rotation about the N-OBn bond of around 10.3 kcalmol-1.32 Like its /V-chloro analogue, the amide isomerisation barrier in 43 is too low to be observed by 3H NMR and even though there is definitive X-ray and theoretical evidence for anomeric effects in /V-acyloxy-/Y-alkoxyamidcs, the barrier to isomerisation about the N-OBn bond must be lower than 10.3 kcalmol-1. The n0-CN ci anomeric interaction in 44 is predicted to be stronger than the n0-CN OAc interaction in 43 on purturbation arguments.32... 

Anomeric effects are evident from dynamic NMR studies on at least one substrate, N-benzyloxy-Af-chlorobenzamide (2c) ". In acetone-de the benzyl aromatic signal (S 7.85) de-coalesced into two signals (ratio 2 1) close to 200 K, corresponding to a free energy barrier of ca 10-11 kcalmoH Amide isomerization appeared to be faster than N—0 rotation since benzoyl resonances were largely unaffected. 

As we have seen, the anomeric effect confers a double-bond character to each C—0 bond of conformer D the energy barrier for a C —0 bond rotation in acetals must therefore be higher than that observed in simple alkanes. Borgen and Dale (41) may have provided the first evidence for this point by observing that 1,3,7,9-tetraoxacyclododecane (37) has a much higher conformational barrier (11 kcal/mol) than comparable 12-membered rings such as cyclododecane (7.3 kcal/mol (42) or 1,4,7,10-tetraoxacyclododecane (5.5 and 6.8 kcal/mol (43)). It was also shown that the two 1,3-dioxa groupings in 37 exist in a conformation identical to that of dimethoxymethane, i.e. the conformation D. 

Anet and Yavari (44) have studied chloromethyl methyl ether by low temperature proton nmr spectroscopy. Their results show that this compound exists in the gauche conformation 38 and they observed a barrier of 4.2 kcal/mol for the rotation of the O-CHjCl bond. This barrier is appreciably higher than that expected on the basis of steric repulsion alone. A rough estimate of the steric barrier is 2 kcal/mol, and they concluded that the anomeric effect increases the barrier to rotation of the O-CHgCl bond by approximately 2 kcal/mol. 

Anomeric Effect and Rotational Barriers Anomeric Effect and Structure I. Bond Lengths and Angles... 

Wiberg KB, Murcko MA (1989) Rotational barriers 4. Dim-ethoxymethane—the anomeric effect revisited. J Am Chem Soc lll(13) 4821-4828... 

The DEL options provide a powerful, flexible methodology for isolating and characterizing the energetic and structural consequences of specific NAO, NHO, or NBO interactions. Illustrative examples include investigations of internal rotation barriers, anomeric effects, and hydrogen bonding. ... 

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