Theor. Chem. Acc. 138, 62 (2019)

DOI: 10.1007/s00214-019-2424-3

Gas‑phase reactivity tuned through the interaction with alkaline‑earth derivatives

The cooperativity between MX2:XH alkaline-earth bonds and XH:NH3 hydrogen bonds (M = Mg, Ca; X = F, Cl) was investigated at the G4 level of theory. The cooperativity between these two non-covalent linkages is extremely large, to the point that the increase in their bond dissociation enthalpies may be as large as 240%. More importantly, the weaker the interaction, the larger the increase, so in some cases the linkage that stabilizes the most is the alkaline-earth bond, whereas in others is the hydrogen bond. In all cases, the formation of the MX2:XH:NH3ternary complex is followed by a spontaneous proton transfer, very much as previously found for the Be-containing analogues. Similarly, MX2:FCl:NH3 complexes evolve from a chlorine-shared ternary complex (MX2F···Cl···NH3) or from an ion pair (MX2F−···NH3Cl+) if M = Ca. Although F is the only halogen without σ-hole, MgCl2 derivatives induce the appearance of a σ-hole on it, though less deep than those induced by BeCl2. We have also studied whether Mg and Ca bond-containing complexes MR2:FY (R = H, F, Cl; Y = NH2, OH, F, Cl) may react to form radicals, as it has been found for the Be-containing analogues. These interactions provoke a drastic decrease in the F–Y bond dissociation enthalpy, very much as the one reported for the corresponding Be-analogues, to the point that in some cases the formation of the corresponding MR2F• + Y· radicals becomes exothermic. Hence, the general conclusion of this study is that Mg or Ca derivatives give place to similar or even larger perturbations on the electron density than those induced by Be, a result not easily predictable.