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Relationship between proton—proton NMR coupling constants and substituent electronegativities. VFor Parts I-IV, see Refs 1-4, respectively. - Empirical substituent constants deduced from ethanes and propanes (1989)

Altona, Cornelis ; Ippel, Johannes H. ; Hoekzema, Aldert J. A. Westra ; [et al.]

Chichester : Wiley-Blackwell

Organic Magnetic Resonance 27 (1989), S. 564-576

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ISSN: 0749-1581

Keywords: Electronegativity ; Proton NMR spectroscopy ; NMR couplings ; Monosbustituted ethanes ; 1,1-Di-substituted ethanes ; Substituent constants ; Chemistry ; Analytical Chemistry and Spectroscopy

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology

Notes: The electronegativity dependence of the torsion angle-independent term in the Karplus equation, i.e. of the ‘constant’ A in the Fourier expansion A + B cos φ + C cos 2φ +…, was investigated. Experimental proton-proton coupling constants of substituted ethanes and isopropanes appeared to be suitable for this purpose. A data set was constructed which contained 70 couplings, newly measured or remeasured at 300 MHz, and 25 couplings taken from the literature. The accuracy of each data point is estimated as ≤0.02 Hz, with a few exceptions. The actual analysis was carried out on 93 data points, i.e. on J values of 55 mono- and of 38 1,1-di-substituted ethanes, including 22 isopropyl derivatives. A total of 55 chemical groups is represented in the set; some of these were taken together, leaving 50 distinct groups. Regression analysis of the present data versus standard electronegativities did not yield acceptable results. Instead, substituent parameters λe, valid for 3J(HH) in saturated H—C—C—H fragments, were derived in a least-squares procedure from the data set. The couplings from mono- and 1,1-di-substituted ethanes could be accounted for in a simple expression that contains an interaction term C012(λ1λ2). The best equation obtained is \documentclass{article}\pagestyle{empty}\begin{document}$$ {}^3J{\rm (HH) = 7}{\rm .84 - 0}{\rm .59(}\lambda _{\rm 1} + \lambda _{\rm 2}) - 0.42(\lambda _{\rm 1} \lambda _{\rm 2}) $$\end{document} The parameters are valid for λe values scaled according to the Huggins electronegativities: λH = 0, λOR = 1.40. The equation fits 84 experimental couplings with a root-mean-square deviation of 0.018 Hz and a maximum deviation of 0.06 Hz. Some exceptions occur. (i) CH3CH3, CH3CHCl2 and CH3CHF2 appear to follow a different, but correlated, regression; (ii) C(=O)H, C(=O)R, SO2Cl and POCl2 groups require different λe values according to the substitution pattern, i.e. mono- or 1,1-di-substitution. The striking difference between the new λe substituent-effect scale and other empirical electronegativity scales lies in the inverse correlation of λe with increasing electronegativity of β-substituents. The inverse relationship is not only found for α-carbon atoms, but appears to represent a general phenomenon, also seen for substituted α-hetero atoms (O, N, S).

Additional Material: 8 Tab.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/mrc.1260270609

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Relationship between proton - proton NMR coupling constants and substituent electronegativities. IVFor Parts I, II, III and V, see Refs 1, 2, 3 and 4, respectively. - An extended karplus equation accounting for interactions between substituents and its application to coupling constant data calculated by the Extended Hückel method (1989)

Donders, Lambertus A. ; De Leeuw, Franciscus A. A. M. ; Altona, Cornelis

Chichester : Wiley-Blackwell

Organic Magnetic Resonance 27 (1989), S. 556-563

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ISSN: 0749-1581

Keywords: Karplus equation ; Proton NMR spectroscopy ; NMR couplings ; Substituted ethanes ; Substituent constants ; Electronegativity ; Chemistry ; Analytical Chemistry and Spectroscopy

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology

Notes: Some well known Karplus equations are discussed and their shortcomings are indicated. To remedy the problems associated with the experimentally observed non-additive substituent effects on vicinal proton-proton coupling constants, an extension given recently is discussed; this accounts for pairwise interactions between substituents through specific quadratic cross terms used to describe the electronegativity dependence of the coefficients in a truncated Fourier series. Since this formulation will be used in combination with simultaneous least-squares optimization of both the Fourier coefficients and the electronegativity values, an invariance property of this formulation, and of similar ones, is discussed in order to elucidate problems associated with parameter redundancy. The procedure is then applied in a stepwise manner to the analysis of a set of 1404 coupling constants calculated by a repara-meterized version of the Extended Hückel method for ethanes singly or multiply substituted with Cl, F, Me and OH, and ethane itself. This clearly reveals its essential features, and leads to a markedly improved description.

Additional Material: 1 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/mrc.1260270608

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