[(thf)Li₂{H₂CS(N^tBu)₂}]₂: Synthesis, Polymorphism, and Experimental Charge Density to Elucidate the Bonding Properties of a Lithium Sulfur Ylide

Abstract: Sulfur ylides (R 2 S + --CR 2 ) are widely used in organic synthesis for stereoselective epoxidations, cyclopropane formations, and ring expansion reactions. Nevertheless, their electronic properties are still under debate, because their ylenic textbook formulation (R 2 SdCR 2 ) contradicts the reactivity. In order to elucidate the electronic situation in a sulfur ylide, we present an experimental charge density study via multipole refinement and subsequent topological analysis based on high-resolution X-ray d… Show more

“…The Bader and Hirshfeld charges of the water oxygen OW atom are higher than the respective charges of the P-bonded O atom. The Bader Li charges are practically the same as reported earlier (Deuerlein et al, 2008;Mermer & Starynowicz, 2011), whereas the Hirshfeld ones are slightly lower than the previously reported and the theoretical values. It may also be noticed that Q H of the hexacoordinate Li2 is somewhat higher than Q H of the tetrahedral Li1 -probably because of larger Li-O distances in the former case.…”

Electron density distribution in tetralithium hypodiphosphate hexahydrate, Li₄P₂O₆·6H₂O

“…The Bader and Hirshfeld charges of the water oxygen OW atom are higher than the respective charges of the P-bonded O atom. The Bader Li charges are practically the same as reported earlier (Deuerlein et al, 2008;Mermer & Starynowicz, 2011), whereas the Hirshfeld ones are slightly lower than the previously reported and the theoretical values. It may also be noticed that Q H of the hexacoordinate Li2 is somewhat higher than Q H of the tetrahedral Li1 -probably because of larger Li-O distances in the former case.…”

Electron density distribution in tetralithium hypodiphosphate hexahydrate, Li₄P₂O₆·6H₂O

“…The use of the density-related bonding angles leads to a higher agreement with those anticipated from the VSEPR theory (Figure 8). [73][74][75][76][77] Covalent bonds are characterized by an overlapping of the valence shells, more specific the VSCCs, which refer to the valence shell regions of the bonding partners. This causes an accumulation of charge density (5 2 1A C H T U N G T R E N N U N G (r BCP ) < 0) in the bonding region and therefore at the BCP.…”

“…is especially interesting, [77] as in addition to the formal hypervalency discussed above, the controversial interaction of a carbanion with a Li 3 triangle can be investigated. The coordination of a carbanion to a Li 3 triangle, [109] a structural motif wellknown throughout organolithium chemistry, is also present…”

Meaningful Structural Descriptors from Charge Density

“…[9] These charges originate from bond polarization effects as well as from charge transfer between the atoms. [18] The integrated charges are given in Table 2, together with the atomic net charges, which are calculated from the difference in the number of valence electrons and the refined mono-A C H T U N G T R E N N U N G pole populations of the atoms. The integrated charges of the nitrogen atoms are about one order of magnitude higher than the net charges.…”

Catalytic Abilities of [(C₆F₅)₂BR] (R=NC₄H₄and NC₄H₈) Deduced from Experimental and Theoretical Charge‐Density Investigations