Bonding situation and stability of η¹- and η⁶-bonded heteroarene complexes M(η¹-EC₅H₅)₆ and M(η⁶-EC₅H₅)₂ (M = Cr, Mo, W; E = N, P, As, Sb, Bi)

Density functional calculations at the BP86/TZ2P level are reported for the pseudo-octahedral heteroarene complexes M(η¹-EC₅H₅)₆ and for the sandwich complexes M(η⁶-EC₅H₅)₂ (M = Cr, Mo, W; E = N, P, As, Sb, Bi). The complexes M(CO)₆ and M(η⁶-C₆H₆)₂ have been calculated for comparison. The nature of the metal-ligand interactions was analyzed with the EDA (energy decomposition analysis) method. The calculated bond dissociation energies (BDE) of M(η¹-EC₅H₅)₆ have the order for E = P > As > N > Sb ≫ Bi and for M = Cr < Mo < W. All hexaheteroarenes bind more weakly than CO in M(CO)₆. Except for pyridine, which is the weakest η⁶-bonded ligand, the trend in the BDE of the M(η⁶-EC₅H₅)₂ complexes is opposite to the trend of the M(η¹-EC₅H₅)₆ complexes NC₅H₅ < PC₅H₅ < AsC₅H₅ < SbC₅H₅ < BiC₅H₅. The opposite trend is explained with the different binding modes in M(η⁶-EC₅H₅)₂ and M(η¹-EC₅H₅)₆. The bonding in the former complexes mainly takes place through the π electrons of the ligand which are delocalized over the ring atoms while the bonding in the latter takes place through the lone-pair electrons of the heteroatoms E. The Lewis basicity of the group-15 heterobenzenes EC₅H₅ becomes weaker for the heavier elements E. The occupied π orbitals of the heterobenzene ring become gradually more polarized toward the five carbon atoms in the heavier arenes EC₅H₅ which induces stronger metal-carbon bonds in M(η⁶-EC₅H₅)₂ and weaker metal-E bonds. The EDA calculations show that the nature of the M-EC₅H₅ bonding in M(η¹-EC₅H₅)₆ is similar to the M-CO bonding in M(CO)₆. Both types of bonds have a slightly more covalent than electrostatic character. The π orbital interactions in the chromium and molybdenum complexes of CO and heterobenzene are more important than the σ interactions. This holds true also for the tungsten complexes of CO and the lighter heteroarenes while the σ- and π-bonding in the heavier W(η¹-EC₅H₅)₆ species have similar strength. The EDA results also show that the nature of the bonding in the sandwich complexes M(η⁶-EC₅H₅)₂ is very similar to the bonding in the bisbenzene complexes M(η⁶-C₆H₆)₂. The orbital interactions contribute for all metals and all arene ligands about 60% of the attractive interactions while the electrostatic attraction contributes about 40%. The largest contribution to the orbital term comes always from the δ orbitals. The calculations predict that the relative stability of the sandwich complexes M(η⁶-EC₅H₅)₂ over the octahedral species M(η¹-EC₅H₅)₆ increases when E becomes heavier and it increases from W to Mo to Cr when E = N, P, As.