Stability and bonding situation of electron-deficient transition-metal complexes. Theoretical study of the CO-labilizing effect of ligands L. See abstract

The geometries of the formal 18-valence-electron (VE) complexes [W(CO)₅L] with the π- and σ-bonded monodentate ligands L = N₂, NCH, C₂H₂, C₂H₄, OH₂, SH₂, NH₃, F^-, Cl^-, OH^-, SH^- and those of [W(CO)₄L]^2- with the bidendtate ligands L^2- = O₂C₂H₂^2-, S₂C₂H₂^2- have been calculated at the B3LYP level of theory. The structures of the 16-VE complexes [W(CO)₄L] and [W(CO)₃L]^2- have also been optimized. The bonding situation of the 16- and 18-VE complexes was analyzed with the help of the CDA and NBO partitioning schemes. The goal of the study was to investigate the labilizing influence of the ligand L on the W-CO bonds in the 18-VE complexes and the stabilizing effect on the 16-VE species. Three different structural isomers of the 16-VE species with monodentate ligands have been found as energy minima. All complexes [W(CO)₄L] have either distorted-trigonal-bipyramidal structures with L in the equatorial position (cis1) or square-based-pyramidal forms with L in the basal position (cis2) as the global energy minimum. Square-based-pyramidal structures with L in the apical position (trans) are energetically high-lying minima which have a different electronic state than the cis1 form. The ligand HCCH becomes a 4-electron donor in [W(CO)₄-(HCCH)](cis1) via donation from the out-of-plane π-orbital of acetylene, which significantly stabilizes the 16-VE complex. This mechanism is clearly weaker in the π-NCH complex, and it is very weak in the π-bonded dinitrogen and ethylene complexes. The negatively charged ligands F^-, Cl^-, OH^-, and SH^- have also a strong CO-labilizing effect in [W(CO)₅L]^- because the ligands stabilize the formal 16-VE species [W(CO)₄L]^- by electron donation from the p(π) lone-pair donor orbital. The stabilization by the negatively charged ligands is slightly weaker than that of HCCH. The σ-bonded ligands SH₂, NH₃, and N₂ stabilize [W(CO)₄L] very poorly, and the ligands OH₂ and σ-NCH are only weakly stabilizing. The high stability of the 16-VE complexes with bidentate ligands [W(CO)₃(X₂C₂H₂)]^2- (X = O, S) cannot solely be explained with strong W←X₂C₂H₂^2- π-donation, which is already operative and even stronger in the 18-VE parent complexes [W(CO)₄(X₂C₂H₂)]^2-. An important additional reason for the stability of the complexes [W(CO)₃(X₂C₂H₂)]^2- lies in the ability of the ligands X₂C₂H₂^2- to enhance the bond strength of the three W-CO bonds.