Attractive metallophilic (aurophilic, argentophilic, cuprophilic, etc.) interactions play an important role in arrangement and stabilization of oligonuclear metal ion complexes. We report a combined experimental and theoretical assessment of aurophilic interactions in closed-shell gold(I) dimers.
The experimental binding energies were obtained for charged [(LH)AuCl](+)...[(L')AuCl] dimers (L is either a phosphine or an N-heterocyclic carbene ligand) in the gas phase. These energies served for benchmarking of correlated quantum chemical calculations (CCSD(T)-calibrated SCS-MP2/CBS method) that were then applied to neutral [(L)AuCl]...[(L')AuCl] dimers.
The overall attractive interactions between monomeric units are in the order of 100165 kJ mol1 in the charged dimers and of 70-105 kJ mol(-1) in the corresponding neutral dimers. In the neutral dimers, pure aurophilic interactions account for 25-30 kJ mol(-1), the dipoledipole interactions for 30-45 kJ mol(-1), and the L...L' "inter-ligand" dispersion interactions for 5-25 kJ mol(-1).
Energy of the aurophilic interactions is thus comparable or even larger than that of strong hydrogen bonds.