Carbon-13 isotope effect on proton decoupled 13C and 31P n.m.r. spectra of bis(diphenylphosphino)acetylene

High resolution proton decoupled ¹³C and ³¹P n.m.r. spectra of bis(diphenylphosphino)acetylene in (CD₃)₂SO and CDCl₃ are analysed as ABX spectra to give the relative chemical shifts of the ¹³C and ³¹P nuclei as well as the spin–spin coupling constants ³J(PP) and ⁿJ(PC). The differences in ³¹P shieldings are due to secondary ¹³C isotope effects which have been observed to be negligible over more than two bonds.     

Determination of 31P,31P coupling constants in cyclotriphosphazenes and their influence on 1H and 13C NMR spectra of phosphorus substituents

¹H and ¹³C NMR spectra of symmetrically substituted cyclotriphosphazenes exhibit second‐order effects. The influence of the ³¹P,³¹P coupling constants between ring phosphorus atoms on these effects was studied. Some values of this coupling constant between phosphorus bearing identical substituents were measured using ¹³C satellites of the ³¹P signals or by introduction of a chiral substituent on the third phosphorus atom. Copyright © 2003 John Wiley & Sons, Ltd.     

13C, 1H and 31P dynamic NMR studies of tetraalkyldiphosphanes: Barrier to internal rotation about the P?P Bond in tetraisopropyldiphosphane

The ¹H, ³¹P and ¹³C NMR spectra of tetramethyldiphosphane (1), tetraethyldiphosphane (2) and tetraisopropyldiphosphane (3) have been studied in the temperature range 30 to ?150°C and at magnetic induction up to 5.87 T. In the range ?100 to ?135 °C, the ¹H and ¹³C spectra of 3 show important changes which can be attributed to freezing the interconversion between two equivalent non-trans conformations. The line shape analysis of the ¹³C signals leads to ΔG^≠ = 29.4 kJ mol^?1 at ?113 °C for the dynamic process involved. The spin coupling parameters ¹J(PP) and N(PC) = ¹J(PC) + ²J(PC) observed for 1 in the temperature range 30 to ?120 °C show variations which could be due to a preference for the trans conformation in this diphosphane.     

13C NMR spectra of phosphole–P(IV) dimers; ABX and AA′X 13C?31P coupling in some derived structures

The easily obtained dimers of phosphole oxides, sulfides and methiodides give ¹³C NMR spectra where carbons within three (sometimes four) bonds of each ³¹P nucleus are doublets of doublets and thus constitute X in an AMX spectrum. Most of the spectra have been completely interpreted with the aid of spectral measurements at two magnetic fields. Saturation of the double bonds in dimers of methylphosphole–P(IV) derivatives causes the ³¹P nuclei to have very similar chemical shifts, with Δν not adequately different from ³J(PP) to give first-order coupling. When both ³¹P nuclei couple with a given ¹³C, a second-order (ABX) ³¹C NMR spectrum is obtained. The presence of the effect is revealed by running the ¹³C NMR spectra at high magnetic field; J(AX)+J(BX) is constant at all fields, but spacing between the lines of the multiplet varies. The spectrum of the oxide, with Δν/J=1.44 for the ³¹P spectrum at 36.43 MHz, approaches first order character at 75 MHz; the methiodide spectrum (Δν/J=4.55) is second order at 15 MHz but clearly first order at 50 MHz, and the sulfide (Δν/J=5.6) is nearly first order at 15 MHz. [2 + 2]-Photochemical intramolecular cyclization of the dimer oxides provides cage-like structures where the ³¹P nuclei are chemically equivalent, but magnetically non-equivalent, making the ¹³C signals have the characteristics of X in an AA′X coupling pattern.     

Determination of relative signs of 13C?13C coupling constants in doubly labelled compounds

Analysis of the noise decoupled ¹³C spectra of doubly ¹³C labelled compounds where the two labelled carbons are identical, makes the determination of reltive signs of ¹³C? ¹³C coupling constants possible in a very simple way. The involved carbon form AA'X or AA'B spin systems.     

Identification of N-methylpyrazole analog isomers by 13C NMR

Using several N-methyl pyrazole analogs the utility of ¹³C nmr in determining isomeric structures was examined. The chemical shift assignments of the pyrazole carbons and thus the isomeric structures were determined using a combination of proton coupled and proton decoupled ¹³C nmr spectra.     

Carbon-13 NMR study of isoxazolopyridine systems

The ¹³C NMR spectra of all azabenzenoid isoxazolopyridines and some of their chloro derivatives are discussed. All ¹³C resonances were unambiguously assigned by means of gated decoupled spectra, from which one-bond and long-range ¹³C? ¹H coupling constants have been determined from line splittings.     

31P–31P SPIN-SPIN COUPLINGS IN SYMMETRICAL AND UNSYMMETRICAL DERIVATIVES OF P(NMeNMe)3P

Abstract

The syntheses and characterization of seven new unsymmetrical derivatives of the type YP(NMeNMe)₃PZ are reported. Where Y = O or NPh: Z = S, Se, Br⁺ and where Y = a lone pair, Z = Br⁺ Also reported are the new symmetrical derivatives where Y = Z = (OC)₅W or (OC)₃Ni and the new monovalent cage cations YP(NMeCH₂)₃CMe⁺ where Y = Ph₃C and Br. Conductivity and ³¹P nmr evidence for the formulation of the phosphonium cations is presented. ³J³¹P³¹P couplings, obtained directly from the ³¹P nmr spectra of the unsymmetrical derivatives, are found to rise upon successively oxidizing the phosphorus atoms, and a rationale is offered. This coupling is also extracted from the ¹⁸³W and ⁷⁷Se satellite peaks in the ³¹P spectra of the symmetrical derivatives where Y = Z = (OC)₅W and Se, respectively.

A self-consistent set of assignments of the ³¹P chemical shifts is arrived at for YP(NMeNMe)₃PZ compounds and the useful role of LIS reagents in analyzing their proton spectra is delineated. The ¹³C nmr spectral parameters of these derivatives are also presented.     

13C-NMR-spektroskopie chinoider verbindungen—II: Substituierte 1,4-naphthochinone und anthrachinone

Proton coupled and proton noise decoupled ¹³C-NMR spectra of 18 1,4-napthoquinones and 13 anthraquinones with oxygen, nitrogen and halogen substituents have been measured. The assignment of the spectra was largely achieved with the aid of the two- and three-bond spin-spin coupling between ¹³C and protons and the substituent effects.     

Selective population transfer in 15N and 13C NMR: Signs of 15N?H and 15N?13C coupling constants in secondary amide and iminium salts

The selective population transfer method has been applied to the study of a secondary amide and of the corresponding iminium salt. Important signal-to-noise enhancements were accessible in both fully coupled and proton decoupled ¹⁵N and ¹³C spectra. Moreover, the resolving power of the method was exploited for the accurate determination of long range ¹⁵N¹H coupling constants. Experiments in which the selective inversion of transitions pertaining to the ¹⁵N satellite spectrum of multiplets which themselves constitute the ¹³C satellite spectrum of the main proton resonances could be carried out. The influence of a change from the amide to the iminium structure on the magnitudes and the signs of various ¹⁵N¹H and ¹⁵N¹³C coupling constants is discussed.     

The 1H, 13C and 31P NMR spectra of EZ pairs of some phosphorus substituted alkenes

The olefins Ph₂P(X)CH?CHR [X=lone pair, O, S, Ch₃I; R?Ch₃, ph, P(X)ph₂] have been prepared and their ¹H, ¹³C and ³¹P NMR spectra measured. trans ³J[P(IV)C] (range 18.3–25.7 Hz) is greater than cis ³J[P(IV)C] (range 6.9–11 Hz) but this relationship does not hold for P(III) compounds. In the ³¹P spectra the E isomer absorbs to higher field than the Z isomer for P(III) and P(IV) compounds. The ¹H data are in accord with previous results; average substituent shielding coefficients for ph₂P(X) substituted alkenes are reported.     

Application of the attached proton test technique in 31P NMR spectroscopy

Intensity modulated ³¹P NMR spectra were obtained using the pulse sequence published by Patt and Shoolery. This attached proton test (APT) technique for signal assignment could be applied to systems with long-range heteronuclear couplings in P? O? C? H fragments. In a model system derived from the alcoholysis of P₄S₁₀ the six reaction products were assigned to the six signals in the ³¹P NMR spectrum.     

13C-NMR-spektroskopie chinoider verbindungen—I : Substituierte p-benzochinone und 2-cyclohexenone

Proton coupled and proton noise decoupled ¹³C-NMR spectra of 20 p-benzoquinones and 2-cyclohexenones having oxygen, nitrogen and halogen substituents have been measured. The unequivocal assignment of the spectra was achieved with the aid of the two- and three-bond spin—spin coupling between ¹³C and protons.     

13C NMR spectra of 8-aryl-8-azabicyclo[3.2.1]oct-3-en-2-ones and related compounds

Carbon-13 NMR spectra of various 8-aryl-8-azabicyclo[3.2.1]oct-3-en-2-ones and other related compounds, including tropinone, were determined, and the predominant conformation at the bridgehead nitrogen was established. The full assignment of resonances from proton decoupled and coupled spectra was based on the analysis of the splitting pattern and characteristic chemical shifts. The use of the determined ¹³C NMR spectra in the assignment of ¹³C NMR data in related but more complicated structures is also proposed.     

Conformational equilibria in isomeric methylcyclohexanols studied by 13C NMR spectroscopy

The conformational equilibrium constants for isomeric methylcyclohexanols (cis- and trans-1,2-, 1,3- and 1,4-methylcyclohexanols) have been determined from peak area measurements in the completely proton decoupled low temperature ¹³C NMR spectra of the individual conformers. The ¹³C chemical shifts are discussed in terms of the additive model.     

Etude RMN 13C d'un Dérivé Uniformément Enrichi en 13C. Signe des Valeurs des Constantes de Couplage Observées

The ¹³C NMR parameters of 3-O-acetyl-1,2:5,6-di-O-isopropylidène-α-D-[U-¹³C] glucofuranose, used as a sample for analysis in double labelling biosynthetic experiments, have been measured. Homonuclear double resonance experiments ¹³C? {¹³C} at 62.8 MHz have permitted the determination of all the ¹³C? ¹³C coupling constants. By theoretical computation of spectra, in connection with the second order effects existing at 25.2 MHz and 15.08 MHz, the sign of the coupling constants has been determined. The theoretical computation of spectra took into account all the isotopomers and was calculated with the help of a program (adapted from the LAOCOON program) allowing for the weighted addition of the spectra.     

13C NMR spectral assignments of chlorpromazine and its 5-oxide. Literature correction

The ¹³C chemical shift assignments of title compounds were made on the basis of their coupled and decoupled spectra. The size of the ipso and allylic ¹³CH coupling constants establish unequivocally the identity of symmetry related carbon pairs and show that several assignments reported previously are incorrect.     

NMR and stereochemical studies of non aromatic heterocyclic compounds—II : 13C and 31P NMR of 2-methoxy-1,3,2-dioxaphosphorinanes

¹³C and ³¹P chemical shift data for eight 2-methoxy-1,3,2-dioxaphosphorinanes are reported. Examination of pairs of geometrical isomers, which differ only in the orientation of the OMe substituent on P^III, have shown that both the ³¹P and the ¹³C signals of C_4,6 atoms appear 3–4 ppm at higher field when the OMe is axial compared with the equatorial isomer. This observation can be associated with the 1–3 syn diaxial interaction between the phosphorus axial substituent and the axial hydrogens on C_4,6 and should thus constitute, in the future, a supplementary tool for the structural analysis of this kind of compound. Important long range δ effects were observed both on ¹³C and especially on ³¹P chemical shifts. It is suggested that the high field δ_e effects could reflect a direct stereoelectronic interaction between the P atom and the cyclic C-5 atom. This interpretation is supported by a study of the ³¹P…¹³C coupling constants and their stereochemical dependence.     

31P and 13C NMR study of tribenzolyphosphine (C?C6H5)3 Oriented in a Liquid Crystal

The ¹³C and ³¹P NMR spectra of the triply ¹³C labelled tribenzoylphosphine [] oriented in a nematic phase have been recorded. From the spectral analysis one obtains the average CPC valence bond angle value (95.9°± 0.2), and the phosphorus chemical shift anisotropy Δσ(σ_∥? – σ _⊥) which is equal to 75 ± 15 ppm.