Abstract
The strength of binding, as measured by the equilibrium dissociation energy D(e) of an isolated hydrogen-bonded complex B···HX, where B is a simple Lewis base and X = F, Cl, Br, I, CN, CCH, or CP, can be determined from the properties of the infinitely separated components B and HX. The properties in question are the maximum and minimum values σ(max)(HX) and σ(min)(B) of the molecular electrostatic surface potentials on the 0.001 e/bohr(3) iso-surfaces of HX and B, respectively, and two recently defined quantities: the reduced electrophilicity Ξ(HX) of HX and the reduced nucleophilicity И(B) of B. It is shown that D(e) is given by the expression D(e) = {σ(max)(HX)σ(min)(B)} И(B) Ξ(HX). This is tested by comparing D(e) calculated ab initio at the CCSD(T)(F12c)/cc-pVDZ-F12 level of theory with that obtained from the equation. A large number of complexes (203) falling into four categories involving different types of hydrogen-bonded complex B···HX are investigated: those in which the hydrogen-bond acceptor atom of B is either oxygen or nitrogen, or carbon or boron. The comparison reveals that the proposed equation leads to D(e) values in good agreement in general with those calculated ab initio.