Title: The Activation of Hydrogen by First-Row Transition-Metal Complexes. Final Report

We have assigned the vibrational spectra of Os₁ and Os₂ complexes of propene, butene, and acetylene, and have used them for the assignment of the vibrational frequencies of surface alkenes and alkynes. We have measured the rates of H• transfer from (C₅R₅)Cr(CO)₃H to olefins of many structural types, and have learned that even one substituent on the carbon to which the H• is transferred slows down the reaction considerably. We have shown that these Cr hydrides are useful catalysts for chain transfer during radical polymerization reactions. We have determined the strengths of several M–H bonds (in particular Cr–H ones), and have confirmed that the hydrides of first-row transition metals are particularly useful for generating radicals. We have used H• transfer to terminal methylenes to generate radicals that cyclize. We have shown that (C₅R₅)Cr(CO)₃H can be regenerated under H₂ and is therefore catalytic, but that (P–P)V(CO)₄H cannot be regenerated from H₂ and therefore can only be used stoichiometrically for radical generation. (The V-H bonds are weaker than the Cr–H ones, and the H• transfer to an olefin is therefore faster.) We have found that, under five atm of H₂ pressure, cobaloximes catalyze H• transfer; they efficiently remove an H• from cyclized radicals, and therefore can be used to catalyze the cycloisomerization of some olefins. We have explored the one- and two-electron oxidation of (Ph₃P)₆Cu₆H₆. One-electron oxidation (which is reversible) generates a cation radical, whereas two-electron oxidation generates loss of a hydride (i.e., two electrons and a proton). We have found that the hydricity of (Ph₃P)₆Cu₆H₆ is between 36 and 50 kcal/mol. We have shown that uncongested organic radicals (i.e., TEMPO) can catalyze H• transfer from (C₅R₅)Cr(CO)₃H to congested radicals like Ar₃C•. We have examined the one-electron oxidation of [CpV(CO₃H]^–, and have inferred from the results that the reduction of alkyl iodides with [CpV(CO₃H]^– occurs by one-electron transfer. We have been able to use that reagent to catalyze radical cyclizations from H₂ and appropriate alkyl iodides.