Synthetic, Structural, Spectroscopic, and Theoretical Studies of Structural Isomers of the Cluster Pt₃(μ-PPh₂)₃Ph(PPh₃)₂. A Unique Example of Core Isomerism in Phosphine Phosphido-Rich Clusters

Abstract: Two isomers of the phosphido-bridged platinum cluster Pt(3)(&mgr;-PPh(2))(3)Ph(PPh(3))(2) (2 and 3) have been isolated, and their structures have been solved by single-crystal X-ray diffraction. Compound 2 crystallizes in the orthorhombic space group Cmc2(1) with a = 22.192(10) Å, b = 17.650(9) Å, c = 18.182(8) Å, and Z = 4. Compound 3 crystallizes with 2 molecules of dichloromethane in the monoclinic space group C2/c with a = 21.390(10) Å, b = 18.471(9) Å, c = 19.021(11) Å, beta = 105.27(5) degrees, and Z = 4… Show more

“…These are the first examples of nido 11-vertex diplatinaundecaborane clusters in metallaborane chemistry characterised by X-ray diffraction. There is a PPh 2 group bridging two Pt atoms and the PtϪPt distances [2.6672(11) Å for 1, 2.6357(8)Å for 2] are shorter than the PtϪPt distances in the diplatinaborane [(PMe 2 Ph) 3 ClPt 2 B 10 H 9 (PMe 2 Ph)] (2.863Å ) [10] and considerably shorter than the PtϪPt distances in [Pt 3 (µ-PPh 2 ) 3 Ph(PPh 3 ) 2 ] [11] (average 3.0744Å ) which also has a PPh 2 group as a bridging ligand. The Pt (7)ϪP (1) and Pt(8)ϪP(1) bond lengths are 2.314(4) Å in 1 and 2.2992(10) Å in 2, and 2.299(4) Å in 1 and 2.3013(13) Å in 2, respectively.…”

A New Strategy for the Preparation of Metallaboranes − Solvothermal Synthesis and Structural Characterisation of Two Nido 11‐vertex Diplatinaundecaborane Clusters

“…These are the first examples of nido 11-vertex diplatinaundecaborane clusters in metallaborane chemistry characterised by X-ray diffraction. There is a PPh 2 group bridging two Pt atoms and the PtϪPt distances [2.6672(11) Å for 1, 2.6357(8)Å for 2] are shorter than the PtϪPt distances in the diplatinaborane [(PMe 2 Ph) 3 ClPt 2 B 10 H 9 (PMe 2 Ph)] (2.863Å ) [10] and considerably shorter than the PtϪPt distances in [Pt 3 (µ-PPh 2 ) 3 Ph(PPh 3 ) 2 ] [11] (average 3.0744Å ) which also has a PPh 2 group as a bridging ligand. The Pt (7)ϪP (1) and Pt(8)ϪP(1) bond lengths are 2.314(4) Å in 1 and 2.2992(10) Å in 2, and 2.299(4) Å in 1 and 2.3013(13) Å in 2, respectively.…”

A New Strategy for the Preparation of Metallaboranes − Solvothermal Synthesis and Structural Characterisation of Two Nido 11‐vertex Diplatinaundecaborane Clusters

“…Addition of H 2 O (5 mL) caused the precipitation of 2 as a microcrystalline brown solid (720 mg, 98 %). Elemental analysis calcd (%) for C 26 .…”

Assembling Metal Clusters with Covalent Linkers: Synthesis and Structure of a Quasi‐Planar Pt₁₈ Dendrimer Containing Five Clusters Connected by σ‐Alkynyl Spacers

“…[19] Many more examples of serendipitous, exciting (at least for us!) findings could be given, but I have reached the upper limit of the space offered, such as the first examples of reversible CO2 fixation by a transition-metal complex fully characterized by X-ray diffraction and shown to occur by reversible carbon-carbon bond formation (Scheme 2), [20] still a topical area more than 30 years later, and its application to the catalytic lactone synthesis by telomerization of butadiene and CO2; [21] the discovery of a bridging behaviour for trialkoxysilyl ligands (-Si(OR)3) and their possible dynamic behaviour, [22] which provided an extension of the concept of hemilability to dinuclear complexes (Scheme 3); [23] the first example of migration of a silyl ligand from one metal to another in a heterometallic complex (Scheme 4); [24] the synthesis of the first molecular cyanometallate cage, [(OC)Pd(CN)Mn(C5H4Me)(CO)2]4 containing a meso arrangement of helical units (Scheme 5); [25] a remarkable example of crystallization solvent induced core isomerism in the phosphine, phosphido-rich cluster [Pt3(μ-PPh2)3Ph(PPh3)2] resulting in a change of the metalmetal distance by more than 0.5 Å; [26] the synthesis of unprecedented quinonoid zwitterions (Scheme 6), [27] which have led to a very rich coordination chemistry and most fruitful collaborations with physicists; [28] and the characterization of a triply bridging bonding mode for a cyclopentadienyl ligand in a palladium cluster (Scheme 7). [29] It has also been rewarding to see that rational approaches to molecular design have been successful and that predictions could be verified later, such as that concerning the possibility of a bridging behaviour of phosphine ligands, made in 1989, [30] and realized by H. Werner in 2000.…”

“…Quinonoid zwitterions with a large dipole moment (10 D). [26] Scheme 7. Coordination of a C5H5 ligand in a μ3-η 1 :η 2 :η 2 mode to the [Pd3] 4+ triangular subunit of the mixed-valence [Pd3 II (μ-OAc)4(μ3-Cp)Pd 0 (η 5 -Cp)] cluster.…”

The Chemical Record—A Historical Commentary