Highly electron-rich pincer-type iron complexes bearing innocent bis(metallylene)pyridine ligands: Syntheses, structures, and catalytic activity

The first neutral bis(metallylene)pyridine pincer-type [ENE] ligands (E = Si^II, Ge^II) were synthesized, and their coordination chemistry and reactivity toward iron was studied. First, the unprecedented four-coordinate complexes κ²E,E'-[ENE]FeCl₂ were isolated. Unexpectedly and in contrast to other related pyridine-based pincer-type Fe(II) complexes, the N atom of pyridine is reluctant to coordinate to the Fe(II) site due to the enhanced α-donor strength of the E atoms, which disfavors this coordination mode. Subsequent reduction of κ²Si,Si'-[SiNSi]FeCl₂ with KC₈ in the presence of PMe₃ or direct reaction of the [ENE] ligands using Fe(PMe₃)₄ produced the highly electron-rich iron(0) complexes [ENE]Fe(PMe₃)₂. The reduction of the iron center substantially changes its coordination features, as shown by the results of a single-crystal X-ray diffraction analysis of [SiNSi]Fe(PMe₃)₂. The iron center, in the latter, exhibits a pseudosquare pyramidal (PSQP) coordination environment, with a coordinative (pyridine)-Rfnet→Fe bond, and a trimethylphosphine ligand occupying the apical position. This geometry is very unusual for Fe(0) low-spin complexes, and variable-temperature ¹H and ³¹P NMR spectra of the [ENE]Fe(PMe₃)₂ complexes revealed that they represent the first examples of configurationally stable PSQP-coordinated Fe(0) complexes: even after heating at 70 °C for >7 days, no changes are observed. The substitution reaction of [ENE]Fe(PMe₃)₂ with CO resulted in the isolation of [ENE]Fe(CO)₂ and the hitherto unknown κ²E,E'-[ENE]Fe(CO)₂L (L = CO, PMe₃) complexes. All complexes were fully characterized (NMR, MS, XRD, IR, and ⁵⁷Fe Mössbauer spectroscopy), showing the highest electron density on the iron center for pincer-type complexes reported to date. DFT calculations and ⁵⁷Fe Mössbauer spectroscopy confirmed the innocent behavior of these ligands. Moreover, preliminary results showed that these complexes can serve as active precatalysts for the hydrosilylation of ketones.