One-bond spin−spin coupling constants (SSCCs) between F and C are computed with density functional theory (DFT). Surprisingly, M06L stands out for its striking accuracy, outperforming any other investigated functional, including PBE0, otherwise considered one of the most reliable for couplings involving F. Although the computation of nuclear magnetic resonance (NMR) parameters involving F is known to be a challenging task, even with a rather small basis set as pcJ-1, M06L provides results with a MAD = 11.7 Hz, whereas the average deviation gets as much as 5 times larger for PBE0 (MAD = 60.0 Hz). In the context of SSCCs on the order of 300 Hz, this is particularly remarkable. We find that the accuracy of M06L/pcJ-1 in predicting 1 J FC constants does not stem from a well-suited exchange or correlation part of the functional. Instead, it is believed to arise from a fortuitous cancellation of errors, as revealed by investigating the convergence of the basis set. Our findings also indicate that 1 J FC constants are highly dependent on the amount of exact exchange included in the expression of the functional, with large fractions being critically important to achieving satisfactory results. Studying the effects of the geometry on 1 J FC , we find that optimizing the geometry at the level of theory used to calculate SSCCs generally improves the quality of the results, although the combination of a M06-2X/aug-cc-pVTZ geometry with M06L/ pcJ-1 1 J FC constants best reproduces the experimental data for organofluorine compounds (with the exception of fluoroalkenes).
Ab initio molecular dynamics simulations are used to explore tetrahydrofuran (THF) solutions containing pure LiCl and LiCl with CH3MgCl, as model constituents of the turbo Grignard reagent. LiCl aggregates as Li4Cl4, which preferentially assumes compact cubane-like conformations. In particular, an open-edge pseudotetrahedral frame is promoted by solvent-assisted Li–Cl bond cleavage. Among the Grignard species involved in the Schlenk equilibrium, LiCl prefers to coordinate MgCl2 through μ2-Cl bridges. Using a 1:1 Li:Mg ratio, the plastic tetranuclear LiCl cluster decomposes to a highly solvated mixed LiCl·MgCl2 aggregate with prevalent Li–(μ2-Cl)2–Mg rings and linear LiCl entities. The MgCl2-assisted disaggregation of Li4Cl4 occurs through transient structures analogous to those detected for pure LiCl in THF, also corresponding to moieties observed in the solid state. This study identifies a synergistic role of LiCl for the determination of the compounds present in turbo Grignard solutions. LiCl shifts the Schlenk equilibrium promoting a higher concentration of dialkylmagnesium, while decomposing into smaller, more soluble, mixed Li:Mg:Cl clusters.
Ab initio molecular dynamics simulations are used to explore tetrahydrofuran (THF) solutions containing pure LiCl, and LiCl with CH3MgCl, as model constituents of the turbo Grignard reagent. Solvated LiCl aggregates as Li4Cl4, which preferentially assumes compact cubane-like conformations. In particular, an open-edge pseudo tetrahedral frame is promoted by solvent-assisted Li-Cl bond cleavage. Among the various Grignard species produced by the Schlenk equilibrium, LiCl shows clear preference for MgCl2, combining with it through μ2-Cl bridges. Using a 1:1 Mg:Li ratio, the highly plastic tetranuclear LiCl cluster decomposes to a highly solvated mixed LiCl:MgCl2 aggregate with prevalent Li-(μ-Cl)2-Mg rings and linear LiCl entities. The MgCl2 assisted disaggregation of Li4Cl4 occurs through transient structures analogous to those detected for pure LiCl in THF, which also correspond to various moieties observed in the solid state. This study identifies a synergistic role of LiCl for the determination of the compounds present in turbo Grignard solutions, in a scenario where LiCl shifts the Schlenk equilibrium promoting a higher concentration of strongly reactive dialkylmagnesium, meanwhile decomposing into smaller, more soluble, and putatively more active mixed Mg:Li:Cl clusters.
Ab initio molecular dynamics simulations are used to explore tetrahydrofuran (THF) solutions containing pure LiCl, and LiCl with CH3MgCl, as model constituents of the turbo Grignard reagent. LiCl aggregates as Li4Cl4, which preferentially assumes compact cubane-like conformations. In particular, an open-edge pseudo tetrahedral frame is promoted by solvent-assisted Li-Cl bond cleavage. Among the Grignard species involved in the Schlenk equilibrium, LiCl prefers coordinating MgCl2 through m-Cl bridges. Using a 1:1 Li:Mg ratio, the plastic tetranuclear LiCl cluster decomposes to a highly solvated mixed LiCl·MgCl2 aggregate with prevalent Li-(m2-Cl)2-Mg rings and linear LiCl entities. The MgCl2-assisted disaggregation of Li4Cl4 occurs through transient structures analogous to those detected for pure LiCl in THF, also corresponding to moieties observed in the solid state. This study identifies a synergistic role of LiCl for the determination of the compounds present in turbo Grignard solutions, in a scenario where LiCl shifts the Schlenk equilibrium promoting a higher concentration of dialkylmagnesium, meanwhile decomposing into smaller, more soluble, mixed Li:Mg:Cl clusters.
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