Cluster models and ab initio calculations of (19)F NMR isotropic chemical shifts for inorganic fluorides

(19)F NMR isotropic chemical shift (delta(iso)) calculations are performed in crystallized compounds using the GIAO method with the B3LYP hybrid functional at DFT level. Clusters centered on the studied fluorine atoms mimic the crystalline structures. The 6-311+G(d) basis set is chosen for the central fluorine atom, and the LanL2DZ basis set for the others. The metal atoms are described by the 3-21G(2d) basis set or, when not available, by the CRENBL basis set with the corresponding ECP, and augmented with 2d polarization functions when existing. First, for high-symmetry systems (MF, MF(2), and MF(3) compounds), a systematization of the cluster building up from coordination spheres is proposed, generalized to fluoroperovskites and fluoroaluminates KAlF(4) and RbAlF(4). When applied to rather low symmetry systems such as barium fluorometalates BaMgF(4), BaZnF(4), and Ba(2)ZnF(6), the definition of the coordination spheres is far from easy. Then, for structures built up from a MF(6) octahedron network, we may define different "starting clusters": [FM(2)F(8)] for the shared fluorine atoms, [FMF(4)] for the unshared ones, and [FBa(4)](7+) for the "free" ones. Analogous "starting clusters" are then tested on compounds from the NaF-AlF(3), BaF(2)-AlF(3), and CaF(2)-AlF(3) binary systems and for alpha-BaCaAlF(7) that are also built up from a MF(6) octahedron network. For each of these corresponding fluorine sites, delta(iso) values are calculated with the "starting clusters" and several larger clusters and compared to the experimental delta(iso) values. For the barium-containing clusters, the RMS deviation is equal to 51 ppm. It is suggested that this result may be related to the poor quality of the barium basis sets for which no polarization functions are available for the moment. In total, chemical shifts were calculated for 122 fluorine sites, in a various range of compounds. For the clusters without barium, the ab initio method leads to a RMS equal to 22 ppm, which is a quite nice result keeping in mind that the (19)F chemical shift range is larger than 200 ppm.     

Chemical shifts of F19 NMR in spectra of trifluorovinyl compounds

The regularities of the changes of the chemical shift in the F¹⁹ NMR of trifluorovinyl compounds are discussed in this paper. It has been shown that the conditions , where _F ⁰ is the shift of F¹⁹ in tetrafluorethylene (X=F) are satisfied for the chemical shifts of fluorine in compounds. An increase in the electronegativity of X leads to a decrease in the ionic nature of the C-F₃ bond and to a shift toward weak fields. The effect of X on the and shifts is not linked in a specific way to the electronegativity of the X group and is probably determined by the effect of the electric fields on the shielding of the F¹⁹ nucleus. Increments were calculated from the data obtained on the shifts in trifluorovinyl compounds. The method of increments was used for the assignment of the lines in 1, 2-difluoro olefins. This method for the assignment is confirmed by known data. Several cases for the application of the increment method are proposed. The results of spectral measurements of the F¹⁹ NMR in some trifluorovinyl compounds are given in the experimental part.     

19F NMR chemical shifts and C−F bonds in graphite fluorides

Institute for Inorganic Chemistry, Siberian Branch, USSR Academy of Sciences. Translated from Zhurnal Strukturnoi Khimii, Vol. 30, No. 4, pp. 170–172, July–August, 1989.     

DFT-GIAO calculations of 19F NMR chemical shifts for perfluoro compounds

The (19)F NMR shieldings for 53 kinds of perfluoro compounds were calculated by the B3LYP-GIAO method using the 6-31G(d), 6-31+G(d), 6-31G(d,p), 6-31++G(d,p), 6-311G(d,p), 6-311++G(d,p), 6-311G(2d,2p), 6-311++G(2d,2p), 6-311++G(2df,2p), 6-311++G(3d,2p), and 6-311++G(3df,2p) basis sets. The diffuse functions markedly reduce the difference between the calculated and experimental chemical shifts. The calculations using the 6-31++G(d,p) basis set give the chemical shifts within 10 ppm deviations from experimental values except for the fluorine nuclei attached to an oxygen atom, a four- and a six-coordinated sulfur atom, and FC(CF(3))(2) attached to a sulfur atom.     

On the theory of 19F NMR chemical shifts in polar solvents

Theoretical and Experimental Chemistry -     

Trends in the NMR chemical shifts of F19 and the NQR spectra of Cl35 and Br79 in halonitroalkanes

F¹⁹ NMR chemical shifts _F are reported for fluoronitroalkanes, which are found to show a nearly linear relation to the NQR shifts for the chlorine and bromine analogs. The spin-spin coupling constant J_F-N also indicates that the Hal-C-N angles vary little in the series Hal_nC(NO₂)_4-n. The empirical relation can be used to predict the properties of new halonitromethanes. The observed trends in _F and _Cl when H is replaced by X (with X=Cl, F, or NO₂) for the halonitromethanes indicate the sequence NO₂, F, Cl as regards shift _F towards weaker fields, but the sequence F, Cl, NO₂ as regards shift _Cl towards higher NQR frequencies. The deviations from a linear relation for mixed halonitromethanes containing electron-donor groups indicate either that the distortion of the tetrahedral angle varies with the halogen or that conjugation effects for F¹⁹ NMR are different from those for Cl³⁵ and Br⁷⁹ NQR.     

19F NMR based pH probes: lanthanide(III) complexes with pH-sensitive chemical shifts

Experimental measurements and theoretical analysis of magnetic properties, structural dynamics and acid-base equilibria for several lanthanide(III) complexes with tetraazacyclododecane derivatives as 19F NMR chemical shift pH probes are presented; pKa values vary between 6.9 and 7.7, with 18 to 40 ppm chemical shift differences between the acidic and basic forms for Ho(III) complexes possessing T1 values of 10 to 30 ms (4.7-9.4 T, 295 K).     

Solid-State nuclear magnetic resonance: performance of point-charge distributions to model intermolecular effects in 19F chemical shifts

This contribution presents results from applying two different charge models to take into account intermolecular interactions to model the solid-state effects on the ¹⁹F NMR chemical-shift tensors. The density functional theory approach with the B3LYP gradient-corrected exchange correlation functional has been used because it includes electron correlation effects at a reasonable cost and is able to reproduce chemical shifts for a great variety of nuclei with reasonable accuracy. The results obtained with the charge models are compared with experimental data and with results obtained from employing the cluster model, which explicitly includes neighboring molecular fragments. The results show that the point-charge models offer similar accuracy to the cluster model with a lower cost. Received: 3 October 1999 / Accepted: 3 February 2000 / Published online: 5 June 2000     

19F NMR chemical shifts of CF4 in CO2 over a wide pressure range at different temperatures

¹⁹F NMR chemical shifts of CF₄ in CO₂ under extremely dilute concentrations were precisely determined at 299.8, 314.4 and 328.9 K over a wide range of pressure between 0.4 and 33 MPa. The solvent‐induced chemical shift, where the bulk magnetic susceptibility correction was made, was quantitatively expressed as a function of CO₂ density. Copyright © 2002 John Wiley & Sons, Ltd.     

Correlation between 19F environment and isotropic chemical shift in barium and calcium fluoroaluminates

High-speed MAS (19)F NMR spectra are recorded and reconstructed for 10 compounds from BaF(2)-AlF(3) and CaF(2)-AlF(3) binary systems which leads to the determination of 77 isotropic (19)F chemical shifts in various environments. A first attribution of NMR lines is performed for 8 compounds using a superposition model as initially proposed by B. Bureau et al. The phenomenological parameters of this model are then refined to improve the NMR line assignment. A satisfactory reliability is reached with a root-mean-square (RMS) deviation between calculated and measured values equal to 6 ppm. The refined parameters are then successfully tested on alpha-BaCaAlF(7) whose structure was recently determined. Finally, the isotropic chemical shift ranges are defined for shared, unshared, and "free" fluorine atoms encountered in the investigated binary systems. So, the fluorine surroundings can be deduced from the NMR line positions in compounds whose structure is unknown. Such an approach can also be applied to fluoride glasses.     

19F and 1H NMR spectra of halocarbons

19F NMR chemical shifts and coupling constants are reported for 215 compounds. For 77 of these compounds, 1H NMR spectral data are also given. Long-range couplings, including 8J(F,F) and 5J(F,H), are reported. The complexity of halocarbon spectra owing to the presence of rotational isomers, asymmetric centers, long-range couplings, and chlorine isotope effects are illustrated, and the methods used for analyzing such complex spectra are briefly discussed.     

19F n.m.r spectra of polyfluoroquinolines. Long range inter-ring 19F?19F coupling constants and 19F chemical shifts

The signs and magnitudes of every fluorine–fluorine coupling constant in perfluoroquinoline ( 1 ), 2,4-dichloropentafluoroquinoline ( 2 ) and 2-bromohexafluoroquinoline ( 3 ) have been determined by ¹⁹F n.m.r. These provide an unambiguous assignment of the spectrum of the first compound and its derivatives. Inter-ring fluorine–fluorine coupling constants were found to be positive over an odd number of bonds and negative over an even number of bonds, similar to that observed in proton–proton coupling constants in multicyclic systems. The ¹⁹F chemical shifts of perfluoroquinoline and its protonated salt are reported and directly correlated with SCF MO calculated π-electron densities at both fluorine and bonded carbon atoms.     

The relationship between 19F chemical shifts and calculated electron densities in perfluorinated annulenes

Ab initio calculations for a series of perfluorinated annulenes suggest that there is a linear correlation between the total charge density at fluorine and the fluorine chemical shift. The STO-3G basis set overestimates the degree of pi-electron donation by fluorine.     

The relationship between 19F substituent chemical shifts and electron densities: meta- and para-substituted benzoyl fluorides

The ¹⁹F substituent chemical shifts (SCS) of meta- and para-benzoyl fluorides are found to correlate well with substituent parameters using the dual substituent parameter (DSP) equation, indicating that they reflect electronic perturbations induced by the substituent. The direction of the SCS values is such that donating substituents cause upfield shifts whilst acceptors cause downfield shifts. STO-3G calculations indicate that substituents induce only very small changes in π-electron density about the fluorine atom, but that these changes correlate reasonably well with the observed SCS values. For the para series, the slope of the relationship between δq and ¹⁹F SCS is 5000 ppm/electron, indicating the great sensitivity of the flourine atom to small changes in electron density.