Synthesis, Kinetic Studies, and Structural Investigations of Osmium and Ruthenium Clusters

Addition reactions of ten neutral nucleophiles and seven anionic nucleophiles with the pentaosmium pentadecacarbonyl carbido cluster Os5C(CO)15 have been kinetically studied and several important reactivity trends have been established. The calculated activation parameters support an associative mechanism involving the attack of nucleophiles on the parent cluster in the rate-limiting step. Decarbonylation reactions of neutral arachno clusters Os5C(CO)15L have also been kinetically studied and different reactivity trends have been observed. Reactions of Os5C(CO)15 with both neutral and anionic nucleophiles produce corresponding arachno clusters in good yield. Neutral arachno clusters decarbonylate when heated to yield corresponding nido clusters. All studied anionic arachno clusters are resistant to decarbonylation, but most of them readily react with organic acids to form corresponding hydrido clusters. Reactions of anionic arachno clusters with methyl triflate yielded several new clusters. Exploration of metal-ligand bond lengths in the respective pairs of arachno and nido clusters yielded a valuable conclusion with regard to steric effects prevalent in these molecules. The mechanisms for polyhedral structural rearrangements between arachno and nido derivatives of the pentaosmium carbido cluster have been proposed. Thermolysis of cluster Ru3[Ph2PCH(Me)PPh2](CO)10 in the presence of diphenylacetylene yields alkyne-substituted clusters Ru3(PhCCPh)[Ph2PCH(Me)PPh2](CO)8 and Ru3(PhCCPh)[Ph2PCH(Me)PPh2](CO)7 as the major products. The backbone-modified diphosphine in both clusters has facilitated the growth of single crystals suitable for X-ray crystallography. The kinetics for the conversion between two clusters have been investigated and the calculated activation parameters were found to be inconsistent with a rate-limiting step involving a dissociative loss of CO.