Tuning a phosphine-substituted diimine ligand to afford an iron monocarbonyl complex

A series of low-valent iron complexes that feature a phosphine-substituted α-diimine (DI) ligand have been synthesized. Reduction of (^Ph2PPrDI)FeBr₂ with an excess of Na/Hg in the presence of carbon monoxide afforded the corresponding dicarbonyl complex, (^Ph2PPrDI)Fe(CO)₂. Through multinuclear NMR and single crystal X-ray diffraction analysis, this complex was found to possess a 3-coordinate DI ligand. Upon heating for 10 days at 110 °C while applying intermittent vacuum, (^Ph2PPrDI)Fe(CO)₂ was successfully converted to the corresponding monocarbonyl complex, (^Ph2PPrDI)Fe(CO), which was found to feature a tetradentate chelate. Similar reactivity was explored using the analogous bis(tert-butyl)phosphine-substituted ligand, ^tBu2PPrDI. Addition of this chelate to FeBr₂ afforded (^tBu2PPrDI)FeBr₂, and subsequent reduction yielded (^tBu2PPrDI)FeBr, which was found to possess a tridentate DI ligand by single crystal X-ray diffraction. Performing the reduction of (^tBu2PPrDI)FeBr₂ in the presence of CO afforded the corresponding dicarbonyl complex, (^tBu2PPrDI)Fe(CO)₂. Like aryl-substituted (^Ph2PPrDI)Fe(CO)₂, alkyl-substituted (^tBu2PPrDI)Fe(CO)₂ was found to feature a pendant phosphine arm. However, heating (^tBu2PPrDI)Fe(CO)₂ under vacuum did not allow for phosphine substitution and conversion to the corresponding monocarbonyl complex, highlighting the importance of phosphine π-acidity for substitution and the stabilization of low-valent iron.