Theoretical and experimental approaches to the effects of solvation on the small internal rotational potential of benzal fluoride

Schaefer, Ted; Bernard, Guy M.; Bekkali, Younes; McKinnon, David M.

doi:10.1139/v96-180

Cited by 5 publications

(2 citation statements)

References 37 publications

(49 reference statements)

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“…For an internal rotor as light as a vinyl group and for so low rotational barriers (Figure ), this is only a crude approximation. Consequently, in the case in hand, one may expect that rovibrational effects modify values of the involved NMR parameters. − These effects can also be responsible for the previously observed deviations of δ(H11), δ(C11), and δ(C12) from the regression lines and for apparently enhanced contribution of /2 and/3 orientations of the vinyl group.…”

Section: Resultsmentioning

confidence: 97%

Conformational Equilibrium of Cinchonidine in C₆D₁₂ Solution. Alternative NMR/DFT Approach

et al. 2018

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1 H NMR and 13 C NMR chemical shifts as well as conformation dependent vicinal 1 H− 1 H spin−spin coupling constants for cinchonidine in a dilute C 6 D 12 solution have been measured. These data have been interpreted in detail exploiting the results of the extensive quantum chemistry calculations of molecular geometry and NMR parameters of the molecule, performed using the density functional theory (DFT) B3LYP/6-311++G(2d,p) polarizable continuum model (PCM) level of theory. The experimental values of NMR parameters for cinchonidine have been reproduced very well in terms of parameters calculated for key conformers of this molecule. Simultaneously, the analysis has provided us with a lot of information on conformational equilibrium of cinchonidine in the investigated solution. These findings remain in general agreement with the conclusions of other works, based on NOESY spectra or other physicochemical data. Thus, a careful quantitative interpretation of easily measurable NMR chemical shifts can be an independent and valuable source of structural information even in such complex cases as cinchonidine in solution.Article pubs.acs.org/JPCA

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Section: Resultsmentioning

confidence: 97%

Conformational Equilibrium of Cinchonidine in C₆D₁₂ Solution. Alternative NMR/DFT Approach

et al. 2018

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“…As stated above, determining the extent of charge delocalization from the phenoxide anion to the fluoromethyl group will be accomplished by removing the oxy anion, leaving benzyl fluoride. The examination of the solvent and ring substituent effects on these systems has the additional benefit of allowing for a comparison with an important series of papers by Schaefer and co-workers on the benzyl fluoride system. − On the basis of calculations at the HF/6-31G(d)//HF/6-31G(d) and MP2/6-31G(d)//MP2/6-31G(d) levels and NMR studies, they have concluded that the preferred conformation in isolation for benzyl fluoride has the C−F bond oriented in the plane of the aromatic ring and the energetic maximum along the C(Ar)−CH 2 F rotational profile exists when the C−F bond is perpendicular to the ring. As will be shown below, the opposite energetic ordering is predicted when the basis set is augmented with diffuse functions.…”

Section: Introductionmentioning

confidence: 99%

A Computational Study of Charge Delocalization and Ring Fluoro Substituent Effects in 4-Fluoromethylphenoxides

Urban

Tersch

1999

J. Org. Chem.

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The degree of charge delocalization in 4-fluoromethylphenoxide anions has been investigated with ab initio molecular orbital calculations at the Hartree−Fock and MP2 levels and with the B3LYP density functional using the 6-31+G(d) and 6-311+G(2d,p) basis sets. The effect of aqueous solvation on the rotational profiles has been investigated using the AM1−SM2 solvation model. These anions serve as model systems for fluorinated tyrosine derivatives, which have been used as substrates for the enzyme tyrosine phenol-lyase. The importance of the double-bond/no-bond resonance structure has been assessed through an analysis of conformational profiles, geometries and charge distribution. The effect of ring fluorination on the degree of charge delocalization was investigated to aid in the interpretation of previous experimental mechanistic studies of the tyrosine phenol-lyase enzyme. Calculations were also carried out on benzyl fluoride, and the inclusion of diffuse functions was found to result in the perpendicular conformation as the predicted lowest-energy conformation by a small margin. Previous studies with smaller basis sets found the planar structure to be the lowest-energy conformation. The results indicate that the placement of an electron-donating group (O-) in the para ring position acts to increase the fluoride character of the fluoromethyl group and that this effect is not substantially modulated by the placement of fluorines on the ring.

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Advances in theoretical and physical aspects of spin-spin coupling constants

Contreras¹,

Peralta²,

Giribet³

et al. 2000

Annual Reports on NMR Spectroscopy

128

114

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Theoretical and experimental approaches to the effects of solvation on the small internal rotational potential of benzal fluoride

Cited by 5 publications

References 37 publications

Conformational Equilibrium of Cinchonidine in C₆D₁₂ Solution. Alternative NMR/DFT Approach

Conformational Equilibrium of Cinchonidine in C₆D₁₂ Solution. Alternative NMR/DFT Approach

A Computational Study of Charge Delocalization and Ring Fluoro Substituent Effects in 4-Fluoromethylphenoxides

Advances in theoretical and physical aspects of spin-spin coupling constants

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Theoretical and experimental approaches to the effects of solvation on the small internal rotational potential of benzal fluoride

Cited by 5 publications

References 37 publications

Conformational Equilibrium of Cinchonidine in C6D12 Solution. Alternative NMR/DFT Approach

Conformational Equilibrium of Cinchonidine in C6D12 Solution. Alternative NMR/DFT Approach

A Computational Study of Charge Delocalization and Ring Fluoro Substituent Effects in 4-Fluoromethylphenoxides

Advances in theoretical and physical aspects of spin-spin coupling constants

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Product

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Conformational Equilibrium of Cinchonidine in C₆D₁₂ Solution. Alternative NMR/DFT Approach

Conformational Equilibrium of Cinchonidine in C₆D₁₂ Solution. Alternative NMR/DFT Approach