Investigation of iron-ammine and amido complexes within a C3-symmetrical phosphinic amido tripodal ligand

The primary and secondary coordination spheres can have large regulatory effects on the properties of metal complexes. To examine their influences on the properties of monomeric Fe complexes, the tripodal ligand containing phosphinic amido groups, N,N',N ''-[nitrilotris(ethane-2,1-diyl)tris(P,P-diphenylphosphinic amido) ([poat](3-)), was used to prepare [Fe(II/III)poat](-/0) complexes. The Fe-II complex was four-coordinate with 4 N-atom donors comprising the primary coordination sphere. The Fe-III complex was six-coordinate with two additional ligands coming from coordination of O-atom donors on two of the phosphinic amido groups in [poat](3-). In the crystalline phase, each complex was part of a cluster containing potassium ions in which K center dot center dot center dot O=P interactions served to connect two metal complexes. The [Fe(II/III)poat](-/0) complexes bound an NH3 molecule to form trigonal bipyramidal structures that also formed three intramolecular hydrogen bonds between the ammine ligand and the O=P units of [poat](3-). The relatively negative one-electron redox potential of -1.21 V vs. [(FeCp2)-Cp-III/II](+/0) is attributed to the phosphinic amido group of the [poat](3-) ligand. Attempts to form the Fe-III-amido complex via deprotonation were not conclusive but isolation of [Fe(III)poat(NHtol)](-) using the p-toluidine anion was successful, allowing for the full characterization of this complex.

Automated summary

The use of a tripodal ligand containing specific coordination groups allows for the synthesis of iron complexes, and examination of their structures and properties in the crystalline phase. Variations in the primary and secondary coordination spheres can impact the electrochemical properties of metal complexes, leading to different redox reactions.