Zirconium and titanium propylene polymerization precatalysts supported by a fluxional C ₂-symmetric bis(anilide)pyridine ligand

Titanium and zirconium complexes supported by a bis(anilide)pyridine ligand (NNN = pyridine-2,6-bis(N-mesitylanilide)) have been synthesized and crystallographically characterized. C ₂-symmetric bis(dimethylamide) complexes were generated from aminolysis of M(NMe ₂) ₄ with the neutral, diprotonated NNN ligand or by salt metathesis of the dipotassium salt of NNN with M(NMe ₂) ₂Cl ₂. In contrast to the case for previously reported pyridine bis(phenoxide) complexes, the ligand geometry of these complexes appears to be dictated by chelate ring strain rather than metal-ligand π bonding. The crystal structures of the five-coordinate dihalide complexes (NNN)MCl ₂ (M = Ti, Zr) display a C ₁-symmetric geometry with a stabilizing ipso interaction between the metal and the anilido ligand. Coordination of THF to (NNN)ZrCl ₂ generates a six-coordinate C ₂-symmetric complex. Facile antipode interconversion of the C ₂ complexes, possibly via flat C _2v intermediates, has been investigated by variable-temperature ¹H NMR spectroscopy for (NNN)MX ₂(THF) _n (M = Ti, Zr; X = NMe ₂, Cl) and (NNN)Zr(CH ₂Ph) ₂. These complexes were tested as propylene polymerization precatalysts, with most complexes giving low to moderate activities (10 ²-10 ⁴ g/(mol h)) for the formation of stereoirregular polypropylene.