Iridium–Gold Cluster Compounds: Syntheses, Structures, and an Unusual Ligand-Induced Skeletal Rearrangement

Adams, Richard D.; Chen, Ming-Wei; Yang, Xinzheng

doi:10.1021/om3001026

Cited by 19 publications

(26 citation statements)

References 55 publications

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“…In addition, compound 3 contains two SnPh 3 ligands that occupy equatorial coordination sites, one on each of the two Ir(CO) 2 groups. The Ir−Sn bond distances are similar in length, Ir3−Sn1 = 2.6415(18) Å, Ir2−Sn2 = 2.6413 (19) Å, and are similar to those found in the compounds Ir 3 (CO) 6 (SnPh 3 ) 3 -(μ-H) 3 (μ 3 -Bi) 5 and Ir 3 (CO) 6 (SnPh 3 ) 3 (μ-SnPh 2 ) 3 . 27 There is a hydride ligand bridging the Ir−Ir bond between the two tinsubstituted iridium atoms.…”

Section: Inorganic Chemistrysupporting

confidence: 75%

The Addition of Gold and Tin to Bismuth–Triiridium Carbonyl Complexes

Adams

Elpitiya

2015

Inorg. Chem.

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The reaction of Ir3(CO)9(μ3-Bi) with PhAu(NHC) (1), where NHC = 1,3-bis(2,6-diisopropylphenylimidazol-2-ylidene), has yielded the compound Ir3(CO)8(Ph)(μ3-Bi)[μ-Au(NHC)] (2) by the loss of one CO ligand and the oxidative addition of the Au-C (phenyl) bond of 1 to one of the iridium atoms. The Au(NHC) group bridges one of the Ir-Bi bonds of the cluster. On the basis of X-ray crystal structural analysis and molecular orbital and quantum theory of atoms in molecules calculations, the Au-Bi interaction was determined to be substantial and is comparable in character to the Ir-Bi and Ir-Ir bonds in this cluster. Compound 2 reacts with 2 equiv of HSnPh3 to yield the compound Ir3(CO)7(SnPh3)2(μ3-Bi)[μ-Au(NHC)](μ-H) (3), which contains two terminally coordinated SnPh3 ligands. Compound 3 reacts with H2O to yield the compound Ir3(μ3-Bi)(CO)7[μ-Ph2Sn(OH)SnPh2][μ-Au(NHC)] (4) by cleavage of a phenyl ring from each of the SnPh3 ligands and formation of a bridging OH group between the two tin atoms to form a chelating Ph2Sn(OH)SnPh2 ligand.

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Section: Inorganic Chemistrysupporting

confidence: 75%

The Addition of Gold and Tin to Bismuth–Triiridium Carbonyl Complexes

Adams

Elpitiya

2015

Inorg. Chem.

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“…These CO ligands must come from the decarbonylation of glyceraldehyde. The geometry of 2 is a “bow tie” or edge‐sharing bitetrahedron,6 previously unreported for Ir complexes, other than in a Au–Ir cluster 7. In spite of its high‐temperature formation,8 it retains 14 H ligands (according to 1 H NMR spectroscopic data and DFT calculations).…”

Section: Interatomic Distances In 2 As Determined By X‐ray Diffractiomentioning

confidence: 90%

A Carbene‐Rich but Carbonyl‐Poor [Ir₆(IMe)₈(CO)₂H₁₄]²⁺ Polyhydride Cluster as a Deactivation Product from Catalytic Glycerol Dehydrogenation

et al. 2014

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“…9,10 Iridium is well-known for its ability to produce highly active homogeneous 11 and heterogeneous 12 catalysts. Recently, gold nanoparticles have been shown to exhibit significant activity for the catalytic oxidation of CO and for the oxidation and transformations of unsaturated hydrocarbons.…”

Section: And Withmentioning

confidence: 99%

Semibridging Phenyl Ligands in Iridium–Copper and Iridium–Silver Cluster Compounds: Synthesis, Structures, and Bonding

et al. 2013

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Reactions of the tetrairidium anion [Ir 4 (CO) 11 (Ph)] − (1) with [Cu(NCMe) 4 ]- [BF 4 ] and Ag [NO 3 ] have yielded the new iridium−copper and iridium−silver complexes Ir 4 (CO) 11 (μ-η 1 -Ph)[μ 3 -Cu(NCMe)] (2) and [Et 4 N][{Ir 4 (CO) 11 Ph} 2 (μ 4 -Ag)] (3), respectively. Compound 2 consists of a tetrahedral Ir 4 cluster with a Cu(NCMe) group bridging one of the Ir 3 triangular faces of the cluster and a semibridging η 1 -phenyl ligand that is σ−π-coordinated as a bridge across one of the Ir−Cu bonds. The complex anion of 3 contains two Ir 4 (CO) 11 Ph anions linked by a single quadruply bridging silver atom that has adopted a bow-tie geometry between the four iridium atoms. It contains two terminally coordinated σ-phenyl ligands. Compound 3 reacts with a second equivalent of Ag [NO 3 ] to yield the uncharged complex [Ir 4 (CO) 11 ] 2 (μ 4 -Ag)(μ-Ag)(μ 3 -Ph)(μ-Ph) (4), which contains two Ir 4 (CO) 11 clusters linked by a quadruply bridging silver atom and one triply bridging Ph ligand. The second Ag atom in 4 is an edge bridge on one of the Ir 4 clusters, and the second Ph ligand bridges an Ir−Ag bond to it. When it is dissolved in NCMe, compound 4 is split in two and adds 1 equiv of NCMe to the Ag atom in each half to form the compound Ir 4 (CO) 11 (η 1 -Ph)[μ 3 -Ag(NCMe)] (5; 73% yield). Unlike 2, the phenyl ligand in 5 is terminally coordinated. The NCMe ligand is coordinated to the Ag atom. When 4 was treated with PPh 3 , the complex Ir 4 (CO) 11 (μ-η 1 -Ph)[μ 3 -Ag(PPh 3 )] (6) was obtained in 87% yield. The cluster of 6 is structurally similar to that of 5 except that the phenyl ligand has adopted a semibridging coordination to the silver atom, similar to that found between the phenyl ligand and the copper atom in 2. All of the new products were characterized by single-crystal X-ray diffraction analyses. The bonding of the bridging phenyl ligands to the clusters in 2 and 4 was analyzed by DFT computational methods. ■ INTRODUCTIONη 1 -bridging aryl ligands A are commonly found in polynuclear metal complexes of the coinage metals: Cu, Ag, and Au. 1 Aryl copper compounds have been used for a variety of carbon−carbon bond forming cross-coupling reactions. 1a There are relatively few examples of η 1 -bridging aryl ligands in polynuclear transition-metal carbonyl complexes. 2 In most cases, η 1 -bridging aryl ligands bridge two similar metal atoms in a symmetrical fashion and the plane of the ring is approximately perpendicular to the metal−metal bond vector (A). 1,2 Although they are much less common, η 1 -aryl ligands bridging heteronuclear pairs of metal atoms are often coordinated asymmetrically (B). 1a,3 In these unsymmetrical cases, the plane of the aryl ring is usually not perpendicular to the M−M′ bond vector. In analogy to the well-known semibridging behavior of carbonyl ligands, 4 we will, hereafter, refer to these asymmetrical bridging phenyl ligands as semibridging ligands. Viewed without a charge, all η 1 -bridging aryl ligands serve as one-electron donors. η 2 -Bridging aryl ligands C are al...

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Iridium–Gold Cluster Compounds: Syntheses, Structures, and an Unusual Ligand-Induced Skeletal Rearrangement

Cited by 19 publications

References 55 publications

The Addition of Gold and Tin to Bismuth–Triiridium Carbonyl Complexes

The Addition of Gold and Tin to Bismuth–Triiridium Carbonyl Complexes

A Carbene‐Rich but Carbonyl‐Poor [Ir₆(IMe)₈(CO)₂H₁₄]²⁺ Polyhydride Cluster as a Deactivation Product from Catalytic Glycerol Dehydrogenation

Semibridging Phenyl Ligands in Iridium–Copper and Iridium–Silver Cluster Compounds: Synthesis, Structures, and Bonding

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Iridium–Gold Cluster Compounds: Syntheses, Structures, and an Unusual Ligand-Induced Skeletal Rearrangement

Cited by 19 publications

References 55 publications

The Addition of Gold and Tin to Bismuth–Triiridium Carbonyl Complexes

The Addition of Gold and Tin to Bismuth–Triiridium Carbonyl Complexes

A Carbene‐Rich but Carbonyl‐Poor [Ir6(IMe)8(CO)2H14]2+ Polyhydride Cluster as a Deactivation Product from Catalytic Glycerol Dehydrogenation

Semibridging Phenyl Ligands in Iridium–Copper and Iridium–Silver Cluster Compounds: Synthesis, Structures, and Bonding

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A Carbene‐Rich but Carbonyl‐Poor [Ir₆(IMe)₈(CO)₂H₁₄]²⁺ Polyhydride Cluster as a Deactivation Product from Catalytic Glycerol Dehydrogenation