Pyramidal nitrogen inversion hindered by a strong intramolecular hydrogén bond in 2‐diethylaminomethylphenols

Денисов, Г. С.; Gindin, V. A.; Golubev, N. S.; Kol'tsov, A. I.; Смирнов, С. Н.; Sobczyk, Marcin

doi:10.1002/mrc.1260311116

Cited by 13 publications

(25 citation statements)

References 17 publications

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“…Intrinsic effects have been examined by Limbach and co-workers, 7 who, from experiments on NÐ Ð ÐH hydrogen bonding (in HF-collidine), have shown that changes in solvent polarity (mixtures of CDF 3 /CDClF 2 were used as solvent) arising from temperature changes in the range 90-160 K induce a dipole moment in the solute (the F-H-N hydrogen-bonded system) that increases as the temperature is lowered. The induced dipole moment takes the form of charge transfer from N to HF accompanied by a displacement of the proton toward the nitrogen, shown by a large decrease in J( 19 1 H g becomes decreasingly negative and eventually positive as the temperature is raised (as noted above, Refs. 8, 10, 11), then it would seem most probable that the sign of the observed coupling fJ( 15 N, 1 H g for dimethylanthranilic acid is negative.…”

Section: Resultsmentioning

confidence: 93%

A nitrogen‐15 NMR study of hydrogen bonding in 1‐alkyl‐4‐imino‐1,4‐dihydro‐3‐quinolinecarboxylic acids and related compounds

Carlton

Staskun

2006

Magnetic Reson in Chemistry

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The title compounds contain groups (amine, amide, imine, carboxylic acid) that are capable of forming intramolecular hydrogen bonds involving a six-membered ring. In compounds where the two interacting functional groups are imine and carboxylic acid, the imine is protonated to give a zwitterion; where the two groups are imine and amide, the amide remains intact and forms a hydrogen bond to the imine nitrogen. The former is confirmed by the iminium 15N signal, which shows the coupling of 1J(15N,1H) -85 to -86.8 Hz and 3J(1H,1H) 3.7-4.2 Hz between the iminium proton and the methine proton of a cyclopropyl substituent on the iminium nitrogen. Hydrogen bonding of the amide is confirmed by its high 1H chemical shift and by coupling of the amide hydrogen to (amide) nitrogen [(1J(15N,1H) -84.7 to -90.7 Hz)] and to ortho carbons of a phenyl substituent. Data obtained from N,N-dimethylanthranilic acid show 15N-1H coupling of (-)8.2 Hz at 223 K (increasing to (-)5.3 Hz at 243 K) consistent with the presence of a N... H-O hydrogen bond.

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Section: Resultsmentioning

confidence: 93%

A nitrogen‐15 NMR study of hydrogen bonding in 1‐alkyl‐4‐imino‐1,4‐dihydro‐3‐quinolinecarboxylic acids and related compounds

Carlton

Staskun

2006

Magnetic Reson in Chemistry

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“…On lowering the temperature or increasing the concentration (unfortunately quantitative studies of concentration effects on NMR spectra were not possible owing to limited solubility at low temperatures), the intensity of the high-field signal rapidly grows which can, therefore, be assigned to the dimeric Mannich base. The signal consists, however, of two doublets of different intensities characterized by coupling constants 1 J 1 H, 15 N of 67 and 70 Hz, which may therefore be assigned to two dimers with different conformations, e.g. DA and DB.…”

Section: H and 15 N Nmr Spectroscopy Of CL 3 Mbmentioning

confidence: 99%

“…Moreover, the dielectric constant of this solvent is strongly increased when the temperature is lowered. The dielectric constant of CHF 3 -CHF 2 Cl (1 : 1) increases from about 20 at 170 K to 45 at 95 K. 23 In addition, we chose to synthesize and study a 15 15 N) between the hydrogen bond proton and nitrogen for obtaining structural information about the hydrogen bond geometry. Second, we performed UV experiments under similar experimental conditions as chosen for the NMR experiments.…”

Section: Introductionmentioning

confidence: 99%

Dimerization and solvent-assisted proton dislocation in the low-barrier hydrogen bond of a Mannich base: a low-temperature NMR study

et al. 2001

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− · · ·H -N + hydrogen bonds exhibiting a considerable charge separation in the case of the dimers. The thermodynamics of the association process were elucidated by UV and NMR spectroscopy. Interestingly, it was found that the addition of methanol does not change substantially the monomer-dimer equilibrium but leads to a considerable shift of the proton in the monomer towards the nitrogen atom. The effect is smaller but also observable for the dimers. In order to assign molecular structures to the observed species, DFT calculations were performed. They reveal a variety of both monomeric and dimeric conformations of Cl 3 MB exhibiting different hydrogen bond geometries. In particular, two monomeric conformations, bent and planar, were found which exhibit almost the same energy and two proton-transfer dimeric species of similar energy and different dipole moments.

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“…Two types of compounds with high NIR barriers are known among a variety of alkylamines: (1) aziridines (with barriers of b16 kcal mol À1 ) 6 and (2) azanorbornanes (with barriers of b13 kcal mol À1 ). 9,10 In both cases specific effects cause this increase: abnormal angle strain in the aziridine case 8 and strain together with the 'bicyclic effect' in the azanorbornane case. 9,10 In general, azanorbornanes belong to the class of polycyclic amines whose backbone disallows a concerted ring inversion-nitrogen inversion-process.…”

Section: Introductionmentioning

confidence: 96%

“…7 Thus, when NIR barriers are b11 kcal mol À1 , in the absence of stabilization of a nitrogen pyramid via a strong N … H bond (e.g. an intramolecular H-bond 8 ), they may be defined as high NIR barriers. Two types of compounds with high NIR barriers are known among a variety of alkylamines: (1) aziridines (with barriers of b16 kcal mol À1 ) 6 and (2) azanorbornanes (with barriers of b13 kcal mol À1 ).…”

Section: Introductionmentioning

confidence: 99%

A third type of alkylamines possessing high nitrogen inversion-rotation barriers

Belostotskii

Häßner

1999

J. Phys. Org. Chem.

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A new type of alkylamines possessing high nitrogen inversion-rotation (NIR) barriers is described (in general, these are hindered cyclic amines). The increase in barrier values for these amines is caused by an increase in steric interactions in the NIR transition state due to restrictions for N-substituent rotation (usually steric repulsion of N-substituents is decreased on going to a planar NIR transition state of alkylamines). Since these compounds may be essentially different in structure, a comparison between the NIR barriers of homologs is proposed as a criterion for the assignment of amines to this type. According to this criterion, the NIR barriers are drastically increased (3-5 kcal mol À1) on going from NMe or NH (usual amines) to more bulky N-alkylhomologs (amines of the third type). Structures of some of these amines were predicted and their NIR barriers were estimated by MM3.

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Pyramidal nitrogen inversion hindered by a strong intramolecular hydrogén bond in 2‐diethylaminomethylphenols

Cited by 13 publications

References 17 publications

A nitrogen‐15 NMR study of hydrogen bonding in 1‐alkyl‐4‐imino‐1,4‐dihydro‐3‐quinolinecarboxylic acids and related compounds

A nitrogen‐15 NMR study of hydrogen bonding in 1‐alkyl‐4‐imino‐1,4‐dihydro‐3‐quinolinecarboxylic acids and related compounds

Dimerization and solvent-assisted proton dislocation in the low-barrier hydrogen bond of a Mannich base: a low-temperature NMR study

A third type of alkylamines possessing high nitrogen inversion-rotation barriers

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