Beyond the Icosahedron: The Quest for High-Nuclearity Supraicosahedral Metallaboranes

Metal-Stabilized [B8 H8 ]2- Derivatives with Dodecahedral Structure in the Solid and Solution States: [(Cp2 MBH3 )2 B8 H6 ] (Cp=η5 -C5 H5 ; M=Zr (1-Zr) and Hf (1-Hf))

Despite the synthesis and structural characterization of closo-hydroborate dianions, [B_n H_n ]^2- (n=6-12) more than 50 years ago, some ambiguity remains about the structure of [B₈ H₈ ]^2- . Although the solid-state structure of [B₈ H₈ ]^2- was established by single-crystal X-ray studies in 1969, fast rearrangements in solution at accessible temperatures prevented its detailed characterization. We therefore stabilized a derivative of [B₈ H₈ ]^2- by using Cp₂ MBH₃ and structurally characterized two new octaborane analogues, [(Cp₂ MBH₃ )₂ B₈ H₆ ] (Cp=η⁵ -C₅ H₅ ; M=Zr (1-Zr) and Hf (1-Hf)), so that the dynamics of the B₈ skeleton were arrested. The solid-state structures of both 1-Zr and 1-Hf comprise a dodecahedron core protected by {Cp₂ MBH₃ } moieties on both sides of the cluster. Spectroscopic characterization (¹¹ B NMR) validates the intactness of the B₈ dodecahedron core in solution as well. Theoretical calculations establish that the two exo-{Cp₂ MBH₃ } fragments provide structural and electronic structural stability to the B₈ core and its intact dodecahedral dianionic nature. Furthermore, we propose isodesmic equations for the formation of higher analogues of the B_n core (n>8) guarded by different group 4 transition metals. Our analysis suggests that, as we move to higher polyhedra (n>10), the formation becomes unfavourable irrespective of metal.

Directed Syntheses of CS2- and CS3-Bridged Decaborane-14 Analogues

To establish a procedure for single-cage cluster expansion of open cage dimetallaoctaboranes(12), we have investigated the chemistry of nido-[(Cp*M)₂B₆H₁₀] (η⁵-C₅Me₅ = Cp*, 1: M = Co; 2: M = Rh), with diverse chalcogen-based borate ligands. As a result, treatment of nido-1 and nido-2 with Li[BH₂E₃] (E = S, Se, or Te) yielded 10-vertex nido-[(Cp*Co)₂B₇EH₉] (3: E = S; 4: E = Se; 5: E = Te) along with known 10-vertex nido-[(Cp*M)₂B₆H₆E₂] (6: E = S, M = Co; 7: E = Se, M = Co; 8: E = Te, M = Co; 9: E = Se, M = Rh). The geometries of dimetallachalcogenaboranes, 3-9, are isostructural with decaborane(14). Thermolysis of nido-1 and nido-2 with an intermediate, generated from CS₂ and [LiBH₄]·THF reaction in THF, produced nido-[(Cp*M)₂B₆S₂H₄(CH₂S₂)] (10: M = Co; 11: M = Rh) and nido-[(Cp*M)₂B₆S₂H₄(CS₃)] (12: M = Co; 13: M= Rh). Clusters 10-13 are rare species in which one of the B-B bonds is coordinated with a {CS₂}^2- or {CS₃}^2- ligand, generating di(thioborolane) {B₂S₂CH₂} or di(thioboralane)-thione {B₂CS₃} moieties. To examine further the coordination chemistry of CS₂-bridged decaborane(14) analogue nido-10, photolysis was carried out with {M(CO)₅·THF} (M = Mo or W) that led to the isolation of [(Cp*Co)₂B₆S₂H₄(CH₂S₂){M(CO)₅}] (14: M = Mo; 15: M = W), where the {CH₂S₂} moiety is coordinated with one {M(CO)₅} moiety in η¹-fashion. All the synthesized clusters have been characterized by ESI-mass, multinuclear NMR spectroscopy, and IR spectroscopy and structurally solved by single-crystal XRD. Furthermore, DFT calculations probe the bonding of these CS₂- and CS₃-bridged decaborane analogues.

Metal-Rich Metallaboranes: Synthesis, Structures and Bonding of Bi- and Trimetallic Open-Faced Cobaltaboranes

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.

Trimetallic Cubane-Type Clusters: Transition-Metal Variation as a Probe of the Roots of Hypoelectronic Metallaheteroboranes

In an effort to synthesize chalcogen-rich metallaheteroborane clusters of group 5 metals, thermolysis of [Cp*TaCl₄] (Cp* = η⁵-C₅Me₅) with thioborate ligand Li[BH₂S₃] was carried out, affording trimetallic clusters [(Cp*Ta)₃(μ-S)₃(μ₃-S)₃B(R)], 1-3 (1, R = H; 2, R = SH; and 3, R = Cl). Clusters 1-3 are illustrative examples of cubane-type organotantalum sulfido clusters in which one of the vertices of the cubane is missing. In parallel to the formation of 1-3, the reaction also yielded tetrametallic sulfido cluster [(Cp*Ta)₄(μ-S)₆(μ₃-S)(μ₄-O)], 6, having an adamantane core structure. Compound 6 is one of the rarest examples containing the μ₄-oxo unit with a heavier early transition metal, i.e., tantalum. In an effort to isolate selenium analogues of clusters 1-3, we have isolated the trimetallic cluster [(Cp*Ta)₃(μ-Se)₃(μ₃-Se)₃B(H)], 4, from the thermolytic reaction of [Cp*TaCl₄] and Li[BH₂Se₃]. In contrast, the thermolysis of [Cp*TaCl₄] with Li[BH₂Te₃] under the same reaction conditions yielded tantalum telluride complex [(Cp*Ta)₂(μ-Te)₂], 5. Compounds 1-4 are hypo-electronic clusters with an electron count of 50 cluster valence electrons. All these compounds have been characterized by ¹H, ¹¹B{¹H}, and ¹³C{¹H} NMR spectroscopy; infrared spectroscopy; mass spectrometry; and single-crystal X-ray crystallography. The density functional theory calculations were also carried out to provide insight into the bonding and electronic structures of these molecules.

Hypoelectronic 8-11-Vertex Irida- and Rhodaboranes

A series of novel isocloso-diiridaboranes [(Cp*Ir)2B6H6], 1, 2; [1,7-(Cp*Ir)2B8H8], 4; [1,4-(Cp*Ir)2B8H8], 5; [(Cp*Ir)2B9H9], 8; isonido-[(Cp*Ir)2B7H7], 3; and 10-vertex cluster [5,7-(Cp*Ir)2B8H12], 6 (Cp* = η(5)-C5Me5) have been isolated and structurally characterized from the pyrolysis of [Cp*IrCl2]2 and BH3·thf. On the other hand, the corresponding rhodium system afforded 10- and 11-vertices clusters [5-(Cp*Rh)B9H13)], 7, and [(Cp*Rh)2B9H9], 9, respectively. Clusters 1 and 2 are topological isomers. The geometry of 1 is dodecahedral, similar to that of its parent borane [B8H8](2-), in which two of the [BH] vertices are replaced by two [Cp*Ir] fragments. The geometry of 2 can be derived from a nine-vertex tricapped trigonal prism by removing one of the capped vertices. Compounds 4 and 5 are 10-vertex isocloso clusters based on a 10-vertex bicapped square antiprism structure. The only difference between them is the presence of a metal-metal bond in 5. The solid-state structures of 8 and 9 attain an 11-vertex geometry in which a unique six-membered B6H6 moiety is bonded to the metal center. In addition, quantum-chemical calculations have been used to provide further insight into the electronic structure and stability of the clusters. All the compounds have been characterized by IR and (1)H, (11)B, and (13)C NMR spectroscopy in solution, and the solid-state structures were established by X-ray crystallographic analysis.

Hypoelectronic isomeric diiridaboranes [(Cp*Ir)2B6H6]: the "Rule-Breakers"(Cp* = η(5)-C5Me5)

In an effort to synthesize supraicosahedral iridaboranes, pyrolysis of [Cp*IrCl2]2 with excess [BH3·] was carried out, and this synthesis afforded the isomeric iridaborane [(Cp*Ir)2B6H6] clusters 1 and 2. The geometry of 1 was determined to be dodecahedral, i.e., similar to that of [B8H8](2-), whereas 2 was found to exhibit a cluster shape that can be derived from a nine-vertex tricapped trigonal prism by removing one of the capped vertices. The calculation of a large HOMO-LUMO gap further rationalized the isocloso structures for these isomers.