Chromium-manganese selenide carbonyl complexes: Paramagnetic clusters and relevance to C = O activation of acetone

The paramagnetic even-electron cluster, [Et₄N] ₂[Se₂Cr₃(CO)₁₀], was found to react readily with Mn(CO)₅Br in acetone to produce two unprecedented mixed chromium-manganese selenide carbonyl complexes, [Et₄N][Me ₂CSe₂{Mn(CO)₄}{Cr(CO)₅} ₂] ([Et₄N][1]) and [Et₄N]₂[Se ₂Mn₃(CO)₁₀{Cr(CO)₅}₂] ([Et₄N]₂[2]). X-ray crystallographic analysis showed that anion 1 consisted of two Se-Cr(CO)₅ moieties, which were further bridged by one isopropylene group and one Mn(CO)₄ moiety. The dianionic cluster 2 was shown to display a Se₂Mn₃ square-pyramidal core with each Se atom externally coordinated by one Cr(CO)₅ group. The formation of complex 1, presumably via C=O activation of acetone, was further facilitated by acidification of the reaction of [Et₄N]₂[Se₂Cr₃(CO)₁₀] with Mn(CO)₅Br in acetone. Complex 1 readily transformed into 2 upon treatment with Mn₂(CO)₁₀ in a KOH/MeOH/MeCN solution. Cluster 2 was a 51-electron species, which readily converted to the known 49-electron cluster [Se₂Mn₃(CO)₉]^2- upon heating and bubbling with CO. Magnetic studies of the even-electron cluster, [Et₄N]₂[Se₂Cr₃(CO) ₁₀], and the odd-electron species, [Et₄N]₂[2] and [PPN]₂[Se₂Mn₃(CO)₉], were determined by the SQUID measurement to have 2, 3, and 1 unpaired electrons, respectively. In addition, the nature and formation of complexes 1 and 2 are discussed, and the magnetic properties and electrochemistry of [Se ₂Cr₃(CO)₁₀]^2-, 2, and [Se ₂Mn₃(CO)₉]^2- were further studied and elucidated by molecular orbital calculations at the PW91 level of density functional theory.