Double and Triple Resonance Experiments on 2-Bromo-5-Chlorotoluene: Signs of the Ring and Ring-Methyl Proton Coupling Constants

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The p.m.r. spectrum of a 15 mole % solution ofp-fluorotoluene in acetone-& is analyzed at 100 MHz using LAOCN3 and LAME computer programs. The resulting spectral parameters satisfactorily reproduce the methyl proton resonance at 60 MHz. The coupling over six bonds between the fluorine nucleus and the methyl protons is 1.15 + 0.02 Hz and is taken as a measure of t h e n electron contribution to the coupling over five bonds between the fluorine nucleus and the proton inp-fluorobenzene. The o electron contribution to this coupling is discussed for some fluorobenzene derivatives and is shown to depend on the electronegativity of the substituents in a manner completely analogous to proton-proton and other proton-fluorine couplings in benzene and pyridine derivatives.

Section: C) Sigma Electron Contribution To Jph" In Fluorobenzene Dermentioning

confidence: 99%

“…The long-range coupling to the methyl protons in benzene derivatives is remarkably insensitive to substituent effects (1)(2)(3)(4)(5). Coupling between the ring protons shows a characteristic, probably alternating, dependence on the electronegativity of the substituents (6,7).…”

Section: Introductionmentioning

confidence: 99%

Proton Magnetic Resonance Spectrum of Parafluorotoluene. Sigma and Pi Electron Contributions to J_p^H,F

Wasylishen¹,

Schaefer²

1971

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“…The assignment of H-3 and H-5 follows umambiguously from the magnitudes of their couplings to the methyl protons, always being larger than 6~,y'CH"n toluene derivatives (36)(37)(38). Furthermore, 3~3 4 is larger than 'Jq5, as expected from known substituent effects on vicinal coupling constants in benzene derivatives (39,40).…”

Section: Methodsmentioning

confidence: 79%

Concerning in 2-methylphenol and its derivatives. A proximate coupling

Schaefer¹,

Wildman²,

Sebastian³

1985

. Can. J. Chem. 63, 773 (1985). In 2-chloro-6-methylphenol in CCI, solution, ' J :~.~~' , the spin-spin coupling between the hydroxyl and methyl protons, is +68(3) mHz. In this compound, the hydroxyl group lies trans to the methyl group. If the coupling becomes -120 ? 60 5 O H . C H I . mHz in a cis orientation of these two groups, then the apparent vanishing of . J , ,In some derivatives of 2-methylphenol is understandable, as well as its presence in other derivatives. Computations of this coupling imply its proximate mechanism and can rationalize its value of -220 ? 20 mHz in 2-tert-butyl-6-methylphenol. Analogies are noted with ' J , S ) H '~~' in 2-trifluoromethyl phenol and with a coupling in styrene, which also appears to vanish in certain orientations of the vinyl group. TED SCHAEFER, TIMOTHY A. WILDMAN et RUDY SEBASTIAN. Can. J. Chem. 63, 773 (1985). Dans le chioro-2-methyl-o phenol en solution dans le CCI,, la constante de couplage spin-spin, ' J :~.~~' , entre les protons de I'hydroxyle et du groupement methyle est Cgale i +68(3) mHz. Dans ce composC, le groupement hydroxyle occupe une position trans par rapport au groupement methyle. Si la valeur de ce couplage devient egale a -120 2 60 mHz pour une orientation cis de ces deux groupes, on peut alors facilement comprendre I'apparente disparition du 5~: H ' C H ' dans quelques derives du methyl-2 phenol ainsi que sa presence dans d'autres derives. Des calculs de ce couplage suggbrent son m6canisme par proximite et peuvent rationaliser sa valeur de -220 2 20 dans le tert-butyl-2 methyl-6 phenol. On note un certain nombre d'analogies avec les valeurs de ' J :~'~" dans le trifluoromethyl-2 phenol ainsi qu'avec un couplage dans le styrene qui semble aussi disparaitre avec certaines orientations du groupement vinyle.[Traduit par le journal]

“…The long-range spin-spin coupling oonstants I between ring protons and protons or fluorine nuclei in the sidechain of benzene derivatives I have been investigated in some detail (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17). In addition to providing tests of theories of the transmission of spin state information, the couplings are often sensitive to the conformation of the molecule and have been employed in the empirical determination of free energy differences between conformational isomers (17,18).…”

Section: Introductionmentioning

confidence: 99%

Long-range proton–¹⁹F spin–spin coupling interactions in phenyltrifluorosilane

Parr¹,

Schaefer²,

Marat³

1977

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Analysis of the proton magnetic resonance spectrum of phenyltrifluorosilane yields the spin–spin coupling constants between the fluorine nuclei and the protons. These are compared with the analogous long-range coupling constants in benzotrifluoride, toluene, and phenylsilane and are rationalized in terms of coupling mechanisms. The coupling over six bonds is assessed as a base point for the estimation of hindered rotation about the carbon–silicon bond.