A cyclic osmastannyl complex, Os(κ2(Sn,P)-SnMe2C6H4PPh2)(κ2-S2CNMe2)(CO)(PPh3) derived from the osmastannol complex, Os(SnMe2OH)(κ2-S2CNMe2)(CO)(PPh3)2

Structure and Reactivity of [Ru-Al] and [Ru-Sn] Heterobimetallic PPh3-Based Complexes

Treatment of [Ru(PPh3)(C6H4PPh2)2H][Li(THF)2] with AlMe2Cl and SnMe3Cl leads to elimination of LiCl and CH4 and formation of the heterobimetallic complexes [Ru(C6H4PPh2)2{PPh2C6H4AlMe(THF)}H] 5 and [Ru(PPh3)(C6H4PPh2)(PPh2C6H4SnMe2)] 6, respectively. The pathways to 5 and 6 have been probed by variable temperature NMR studies, together with input from DFT calculations. Complete reaction of H2 occurs with 5 at 60 °C and with 6 at room temperature to yield the spectroscopically characterized trihydride complexes [Ru(PPh2)2{PPh2C6H4AlMe}H3] 7 and [Ru(PPh2)2{PPh2C6H4SnMe2}H3] 8. In the presence of CO, 6 forms the acylated phosphine complex, [Ru(CO)2(C(O)C6H4PPh2)(PPh2C6H4SnMe2)] 9, through a series of intermediates that were identified by NMR spectroscopy in conjunction with 13CO labeling. Complex 6 undergoes addition and substitution reactions with the N-heterocyclic carbene 1,3,4,5-tetramethylimidazol-2-ylidene (IMe4) to give [Ru(IMe4)2(PPh2C6H4)(PPh2C6H4SnMe2)] 10, which converted via rare N-Me group C-H activation to [Ru(IMe4)(PPh3)(IMe4)'(PPh2C6H4SnMe2)] 11 upon heating at 60 °C and to a mixture of [Ru(IMe4)2(IMe4)'(PPh2C6H4SnMe2)] 12 and [Ru(PPh3)(PPh2C6H4)(IMe4-SnMe2)'] 13 at 120 °C.

Dithiocarbamate Complexes of Platinum Group Metals: Structural Aspects and Applications

The incorporation of dithiocarbamate ligands in the preparation of metal complexes is largely prompted by the versatility of this molecule. Fascinating coordination chemistry can be obtained from the study of such metal complexes ranging from their preparation, the solid-state properties, solution behavior as well as their applications as bioactive materials and luminescent compounds, to name a few. In this overview, the dithiocarbamate complexes of platinum-group elements form the focus of the discussion. The structural aspects of these complexes will be discussed based upon the intriguing findings obtained from their solid- (crystallographic) and solution-state (NMR) studies. At the end of this review, the applications of platinum-group metal complexes will be discussed.

Tin(IV) Compounds with 2-C6F4PPh2 Substituents and Their Reactivity toward Palladium(0): Formation of Tin-Palladium Complexes via Oxidative Addition

The tin(IV) compounds Me_xSn(2-C₆F₄PPh₂)_4-x (1, x = 1; 2, x = 2) and ClSn(2-C₆F₄PPh₂)₃ (3) were obtained from the reactions of 2-LiC₆F₄PPh₂ with MeSnCl₃ (3:1), Me₂SnCl₂ (2:1), or SnCl₄ (3:1), respectively. The reactions of 2-LiC₆F₄PPh₂ with SnCl₄ in different stoichiometric ratios (4:1-1:1) gave 3 as the main product. Compound Cl₂Sn(2-C₆F₄PPh₂)₂ (4) was formed in the transmetalation reaction of 3 and [AuCl(tht)] but could not be isolated. 1 and 2 react with palladium(0) sources {[Pd(PPh₃)₄] and [Pd(allyl)Cp]} by the oxidative addition of one of their Sn-C_Aryl bonds to palladium(0) with formation of the heterobimetallic complexes [MeSn(μ-2-C₆F₄PPh₂)₂Pd(κC-2-C₆F₄PPh₂)] (5) and [Me₂Sn(μ-2-C₆F₄PPh₂)Pd(κ²-2-C₆F₄PPh₂)] (6) featuring Sn-Pd bonds. The reaction of 3 with palladium(0) proceeds via the oxidative addition of the Sn-Cl bond to palladium(0), thus furnishing the complex [Sn(μ-2-C₆F₄PPh₂)₃PdCl] (7) featuring a Sn-Pd bond and a pentacoordinate Pd atom. Transmetalation of Me_xSn(2-C₆F₄PPh₂)_4-x (x = 1-3) with [Pd(allyl)Cl]₂ gave Me_xClSn(2-C₆F₄PPh₂)_3-x and [Pd(allyl)(μ-2-C₆F₄PPh₂)]₂. For x = 1, the compound MeClSn(2-C₆F₄PPh₂)₂ (generated in situ) reacted with another 1 equiv of [Pd(allyl)Cl]₂ by the oxidative addition of the Sn-Cl bond to palladium(0) and the reductive elimination of allyl chloride, thus leading to [MeSn(μ-2-C₆F₄PPh₂)₂PdCl] (8). The reductive elimination of allyl chloride was also observed in the reaction of 3 with [Pd(allyl)Cl]₂, giving [Sn(μ-2-C₆F₄PPh₂)₃PdCl] (7). All compounds have been characterized by means of multinuclear NMR spectroscopy, elemental analysis, single-crystal X-ray diffraction, and selected compounds by ¹¹⁹Sn Mössbauer spectroscopy. Computational analyses (natural localized molecular orbital calculations) have provided insight into the Sn-Pd bonding of 5-8.