Abstract
Synthesis, isolation, and structural characterization of unique metal rich diamagnetic cobaltaborane clusters are reported. They were obtained from reactions of monoborane as well as modified borohydride reagents with cobalt sources. For example, the reaction of [Cp*CoCl]2 with [LiBH4·THF] and subsequent photolysis with excess [BH3·THF] (THF = tetrahydrofuran) at room temperature afforded the 11-vertex tricobaltaborane nido-[(Cp*Co)3B8H10] (1, Cp* = η5-C5Me5). The reaction of Li[BH2S3] with the dicobaltaoctaborane(12) [(Cp*Co)2B6H10] yielded the 10-vertex nido-2,4-[(Cp*Co)2B8H12] cluster (2), extending the library of dicobaltadecaborane(14) analogues. Although cluster 1 adopts a classical 11-vertex-nido-geometry with one cobalt center and four boron atoms forming the open pentagonal face, it disobeys the Polyhedral Skeletal Electron Pair Theory (PSEPT). Compound 2 adopts a perfectly symmetrical 10-vertex-nido framework with a plane of symmetry bisecting the basal boron plane resulting in two {CoB3} units bridged at the base by two boron atoms and possesses the expected electron count. Both compounds were characterized in solution by multinuclear NMR and IR spectroscopies and by mass spectrometry. Single-crystal X-ray diffraction analyses confirmed the structures of the compounds. Additionally, density functional theory (DFT) calculations were performed in order to study and interpret the nature of bonding and electronic structures of these complexes.
Highlights
IntroductionMolecular boron-rich clusters have found their place in many fields ranging from ceramics and polymers to boron neutron capture therapy and nanomaterials [7,8,9,10]
Polyhedral cage expansion for the synthesis of large clusters has been the objective of boron-rich metallaborane and metallacarborane chemistry over the last six decades [1,2,3,4,5,6].Molecular boron-rich clusters have found their place in many fields ranging from ceramics and polymers to boron neutron capture therapy and nanomaterials [7,8,9,10]
We have explored and reported the chemistry of dicobaltaoctaborane(12) with chalcogenated borohydride, Li[BH2 E3 ] [E = S, Se, or Te] which resulted in the characterization of novel chalcogenated analogues of dicobaltadecaborane(14) [54]
Summary
Molecular boron-rich clusters have found their place in many fields ranging from ceramics and polymers to boron neutron capture therapy and nanomaterials [7,8,9,10]. Those applications along with more fundamental studies of their specific and somewhat unique bonding and electronic structures have been the driving force towards the development of this chemistry [7,11,12]. It is difficult to come up with an integrated scheme aimed at the synthesis of polyhedra bearing definite geometry and composition This is largely due to the undefined and uncontrolled nature of cluster growth from metal synthons or small preformed clusters.
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