It is Instructive to compare the va

It is Instructive to compare the various O2n± species. since they provide an interesting illustration of the effect of varying the number of antibonding electrons on the length and stretching frequency of a bond, as the data in Table 18-1 show.
Table 18-1 Bond Values for Oxygen Species
18-7 Complexes of Dioxygen
Although the most common mode of reaction of molecular oxygen with transition- metal complexes is oxidation, that is, extraction of electrons from the metal (or, on occasion, from the ligand system), in appropriate circumstances the oxygen molecule or dioxygen can become a ligand. The reaction of dioxygen with a complex so as to incorporate the dioxygen intact is called oxygenation, as contrasted to oxidation, in which O2 loses its Identity.
Oxygenation reactions are generally although not invariably reversible. That is, on increasing temperature and/or reducing the partial pressure of O2, the dioxygen ligand is lost by dissociation or transferred to another acceptor (which may become oxidized). The process of reversible oxygenation plays an essential role in life processes. The best-known examples involve the hemoglobin and myoglobin molecules of higher animals; they are discussed in Chapter 31. There are several synthetic oxygen-carrying cobalt complexes (Section 24-33), though it is not always firmly established how the oxygen is bound to the cobalt.
Our principal concern here is with a class of compounds that first came to light in 1963, with Vaska's discovery of the reaction
This reaction is reversible. Diamagnetic dioxygen complexes of Fe, Ru, Rh, Ir, Ni, Pd, and Pt are now known. In all those complexes that have been studied by X-ray diffraction the metal atom and the dioxygen ligand form an isosceles triangle. However, the O—O distances vary greatly, from 1.31 to 1.63 Ao,