The lithium aluminium hydride reduction of cyclohexadienylmanganese complexes

Reduction of cyclohexadienyltricarbonylmanganese or its ring-substituted derivatives with lithium aluminium hydride leads to dihydro-derivatives. Preparative and NMR spectral information is presented and interpreted on the basis of the CH-bridged cyclohexenyl structure recently established for these products by Lamanna and Brookhart [3].     

Boron hydride reduction of transition metal—acetyl complexes

Acetyl complexes of iron(II) and ruthenium(II) of the type (π-C₅H₅)(CO)LM(COCH₃), where L = PPh₃, P(OPh)₃, P(cyclohexyl)₃, PMe₂Ph or CO for M = Fe, and PPh₃ for M = Ru, are rapidly reduced to the corresponding ethyl complexes by BH₃ · THF or B₂H₆/C₆H₆. In some cases hydrido complexes of the type (π-C₅H₅)(CO)LMH are also formed. The reaction has been studied by use of ¹H NMR and the spectrum of (π-C₅H₅)(CO)(PPh₃)FeC₂H₅, which shows several unusual features, is discussed in detail. It is suggested that the rate of reduction increases with increasing electron density at the metal centre.Acetyl complexes of other transition metals, i.e. Ir, Pt, Pd, Co and Mo, are also reduced to the corresponding ethyl compounds by B₂H₆/C₆H₆.     

Synthesis of transition metal—heterocyclic carbene complexes. Oxazol-2-ylidene and oxazolidin-2-ylidene complexes of osmium(II) derived from coordinated tosylmethylisocyanide

Tosylmethylisocyanide, when coordinated to osmium(II), reacts with aldehydes and ketones in the presence of sodium methoxide, to produce oxazol-2-ylidene and oxazolidin-2-ylidene complexes.     

Synthesis of low-valent thiocarbonyl complexes via 1,2-elimination of methylthiol from cis-metal-hydrido-dithiomethylester complexes. Os(cs)(CO)2(PPh3)2 and IrCl(CS)(PPh3)2.

[OS(η²-CS₂Me)(CO)₂(PPH₃)₂]⁺ and [Ir(η²-CS₂Me)Cl(CO)(PPh₃)₂)⁺ react with NaBH₄ giving OsH(CS₂Me)(CO)₂(PPh₃)₂ and IrH(CS₂Me)Cl(CO)(PPh₃)₂ respectively; These compounds contain mutually $\text{cis}$ hydride and η¹-dithiomethylester ligands and upon heating undergo 1,2-elimination of MeSH producing Os(CS)(CO)₂(PPh₃)₂ and IrCl(CS)(PPh₃)₂.     

A novel synthesis of carbene complexes of manganese and molybdenum containing the trichlorogermyl group

A number of carbene complexes of formulas Cl₃GeMn(CO)₄C(OR′)R and C₅H₅Mo(CO)₂(GeCl₃)C(OR′)CH₃ (R = CH₃, C₆H₅; R′ = CH₃, C₂H₅) have been prepared by the reaction of [N(C₂H₅)₄]GeCl₃ with CH₃Mn(CO)₅, C₆H₅Mn(CO)₅, or C₅H₅Mo(CO)₃CH₃ followed by alkylation of the resulting trichlorogermylacylcarbonylmetallate ion. The compound C₅H₅Mo(CO)₂(GeCl₃)$\text{COCH}{}_2\text{CH}{}_2\text{C}$H₂ has been prepared directly by the reaction of [N(C₂H₅)₄]GeCl₃ with C₅H₅Mo(CO)₃(CH₂)₃Br.     

Transition metal–carbene complexes XCVII. π-cyclopentadienyldicarbonylmethylphenylcarbenerhenium

Addition of P(OMe)₃ to [Rh(η³?C₃H₅) (CO)₂] gives [Rh(η³?C₃H₅){P(OMe)₃}₃]; this reacts with hydrogen or silanes to form a species which is an effective hydrogenation catalyst for olefins and a hydrosilylation catalyst for terminal olefins, aldehydes and ketones.     

Transition metal complexes of azo compounds : VI. Cycloaddition of alkynes to the complexed cis-azo group. Stepwise cyclodimerisation of diphenylacetylene to tetraphenylcyclobutadiene tricarbonyliron

The μ-(cis-azo) complexes LFe₂(CO)₆ (L  4-phenyl-3,3-bis(methoxycarbonyl)-1-pyrazoline, 4-isopropyl-3,3-bis(methoxycarbonyl)-1-pyrazoline, 2,3-diazanorbornene, and benzo[c]cinnoline) each contain an activated NN bond which reacts thermally and/or photochemically with the alkynes RC₂R (R  H, CH₃, Ph, COOCH₃) by insertion into the FeN bond to give the novel cycloaduct L(RC₂R)Fe₂(CO)₆. The pyrazoline and diazanorbornene complexes are transformed smoothly into the 1,2,3-diazaferrole derivatives L(RC₂R)Fe(CO)₄. These compounds react with a further molecule of the alkyne to give the “double-addition” products L(RC₂R)₂COFe(CO)₂, which can be converted into the cyclobutadiene derivative π-(RC₂R)₂Fe)CO)₃ if R  Ph; this complex can be synthesized very conveniently in yields of 70% by reaction of diphenylacetylene and the pyrazoline compound LFe₂(CO)₆ at 150°C. It is shown that the cyclodimerisation of the alkyne occurs stepwise.     

Ligand effects on the Pt(II) → Pt(0) reduction of dichlorobis(tertiary phosphine)platinum(II) complexes: Correlations between electrochemical data,spectroscopic data,and electronic ligand parameters

Cyclic voltammetry has been employed to study the diffusive, irreversible platinum(II) → platinum(0) reduction of three sets of structurally related complexes: cis-[PtCl₂P{p-C₆H₄X}₃)₂] (X = H, CH₃, Cl, F, OCH₃, N(CH₃)₂); cis-[PtCl₂(PPh₂R)₂] (R = CH₃, n-C₃H₇, n-C₅H₁₁, n-C₆H₁₃, n-C₁₂H₂₅) and cis-[PtCl₂(PR₃)₂] (R = CH₃, C₂H₅, CH₂ch₂CN). Relationships between the peak potentials for the Pt(II) → Pt(0) reduction and thermodynamic parameters which measure the electronic properties of the ligands are shown to exist for complexes of P{p-C₆H₄X}₃ ligands, implying a thermodynamic origin for the sensitivity of the peak potentials to structural change. Complexes of both P{p-C₆H₄X}₃ and PPh₂R ligands show correlations between peak potentials for reduction and the ³¹P{¹H} NMR spectroscopic parameter, ¹J(¹⁹⁵Pt, ³¹P). Correlations with values of δ(³¹P) exist in both cases, but a correlation with the coordination chemical shift, Δδ(³¹P), exists for complexes of PPh₂R, and not for complexes of P{C₆H₄X}₃. Complexes of PR₃ ligands show no correlation between the peak potentials measured for the Pt(II) → Pt(0) reduction and electronic or spectroscopic parameters, except possibly ¹J(¹⁹⁵Pt, ³¹P).     

Magnetism down to 0.90 K, zero-field splitting, and the ligand field in chromocene

The magnetism of chromocene, Cr(cp)₂ where CP = C₅H⁻₅, has been measured as a function of temperature between 0.90 and 303.2 K. The results are reproduced by complete ligand field theory in slightly distorted C_∞v symmetry (Dt = 1153, Ds = 4212, Dq = 28, ζ = 67, B = 553 cm⁻¹, C/B = 4 and k = 0.37). The ground state ³E₂(a₁e³₂) shows a zero-field splitting, D = 15.1 cm⁻¹, E = 0.     

Prochlorperazine bismethanesulfonate: Sensitive and selective reagent for the spectrophotometric determination of microgram amounts of osmium

Prochlorperazine bismethanesulfonate (PCPMS) is proposed as a new sensitive and selective reagent for the spectrophotometric determination of microgram amounts of osmium. PCPMS forms a red-colored species with osmium(VIII) or osmium(VI) instantaneously at room temperature in 5 M phosphoric acid medium. The red species exhibits maximum absorbance at 529 nm. Beer's law is valid over the concentration range 0.05–3.6 ppm for osmium(VIII) and 0.15–6.4 ppm for osmium(VI). Sandell's sensitivity of the reaction is 2.89 nm cm^?2 for osmium(VIII) and 4.24 ng cm^?2 for osmium(VI). The effects of time, temperature, acidity, order of addition of reagents, reagent concentration, and diverse ions are investigated. The application of the proposed method in the determination of osmium content in synthetic ores has been explored.     

Strength of the PtCS2 bond in Pt(PPh3)2(CS2)

The enthalpy of the reaction: Pt(PPh₃)₂(CH₂CH₂)(cryst.) + CS₂(g) → Pt(PPh₃)₂(CS₂)(cryst.) + CH₂CH₂(g) has been determined as ΔH = ? 4.40 ± 2.2 kJ mol^?1 from solution calorimetry, and the bond dissociation energy D(PtCS₂) shown to be slightly greater than D(PtC₂H₄).     

Palladium(II) complexes with sulfur ylides: A new complex containing methylsulfoxonium dimethylide as a chelating ligand

The complex [CH₃SO(CH₂)₂·PdI]₂ which contains the new methylsulfoxonium dimethylide as a chelating ligand, is described.     

The effect of the central metal charge on the reduction half-wave potentials of d6 metal complexes

A SCF MO calculation is made to obtain the energies of the lowest vacant π-orbitals of tris-2,2′-bipyridine complexes of d⁶ transition metals in various oxidation states. Any overlap of a metal t_2g-orbital and a ligand π-orbital is neglected and the metal ion is considered as a source of an electrostatic potential field. The π-electron system of the three ligand molecules is treated as a whole by taking account of the overlap of 2pπ-AO's belonging to different ligand molecules. When it is assumed that a ligand π^*-orbital is occupied by the electron added in the course of reduction, the results of the calculation and the Born equation for solvation energy together lead to a linear relation between the reduction half-wave potentials of the complexes and the sum of the charges on the central metal ion and the ligand nitrogen atoms. This linear relation is confirmed experimentally by using the available data on the reduction half-wave potentials of the tris-bipyridine complexes of the following d⁶ metals: Ir(III), Fe(II), Ru(II), Os(II), Cr(0), Mo(0), V(?I) and Ti(?II).     

Addition of lithium aluminium hydride to olefins catalyzed by zirconium tetrachloride: A convenient route to alkanes and 1-haloalkanes from 1-alkenes

Lithium aluminium hydride adds to olefins in the presence of zirconium tetrachloride under mild conditions. This facile reaction offers a convenient laboratory method for the hydrogenation of olefins or for the preparation of 1-haloalkanes from olefins in high yield. Unstrained internal olefins appear to be unreactive.     

Solvent,ligand and temperature effects on the rates of reactions of cis-[PdCl2(CNR)(L)] with secondary amines

The kinetics of the reaction of cis-[PdCl₂(CN-p-C₆H₄Cl)(PPh₃)] with N-methylaniline yielding the carbene derivative cis-[PdCl₂ {C(NH-p-C₆H₄Cl)NMePh} (PPh₃)] have been studied in various solvents such as acetone, 1, 4-dioxane, 1,2-dichloroethane, and benzene. Overall rates for the stepwise process increase with decreasing ability of the solvent to form hydrogen bonds with the attacking amine. A kinetic study is also reported for the reactions of N-methylaniline with cis- [PdCl₂(CN-p-C₆H₄Me)(L)] in 1,2-dichloroethane (L = P(OMe)₃, P(OMe)₂Ph, PPh₃. PMePh₂, PMe₂Ph, PEt₃, PCy₃). The cis ligand L affects reaction rates through both steric and electronic factors. The nucleophilic attack of the amine on the CN carbon atom of coordinated isocyanide is favoured by low steric requirements and high π-acceptor ability of L. The activation parameters for the bimolecular nucleophilic attack when L = PPh₃ are △H^≠₂ = 9.8 ± 0.7 kcal/mol and △S^≠₂ = — 30 ± 2 e.u.     

Triplet-doublet electronic energy transfer from benzophenone to the ketyl radical: viscosity and magnetic field effects

The influence of solvent viscosity and an external magnetic field on the rate constant of electronic energy transfer from triplet bonzophenone to the ketyl radical is studied; it is concluded that the transfer is mediated by electron exchange.     

Complex formation of trace elements in geochemical systems—VI: Study on the formation of hydroxo fluoro mixed ligand complexes of the lanthanide elements in fluorite bearing system

The complexation of the rare elements Ce, Eu, Tb and Yb in fluorite bearing model solution of the pH 5–9 and the pF 2–5 has been studied by means of the distribution method. Hydroxofluoro mixed ligand complexes were found to be the most important species formed at pH 7 and pF 3 which are the relevant values of hydrothermal fluorite bearing solutions. The stability constants and the distribution of these complexes as a function of pH and pF were determined.     

Electrocatalysis by ad-atoms: Part VIII. Ag,Pb, Te and Tl ad-atoms for ethylene reduction

As already reported, ethylene reduction at a Pt electrode can be enhanced by ad-atoms of Cu and Hg. Another series of ad-atom species is reported, that is, Ag, Pb, Tl and Te, in which the enhancement order depends on the number of Pt sites occupied by an ad-atom. S_M. This effect originates from the difference between S_M and the number of Pt sites occupied by an ethylene molecule, which causes an increase in the number of Pt sites available for hydrogen adsorption. This increase results in the enhancement, in the order Ag>PbTl; Te which has the same S as ethylene has no enhancement effect.For the complete understanding of the function of the mixed surface in the electrocatalysis, a new concept, “catalytic domains”, parts of the mixed surface effective for the electrocatalysis, is introduced, on the assumption that the reaction rate is much higher than the rate of surface migration of the adsorbed species. Then the number of Pt sites which belong to the catalytic domain is calculated. Another concept, “reaction unit mesh”, is also introduced.     

Electrode kinetics of the metal complexes with aminopolycarboxylic acids: Part II. Cadmium-ethylenediamine-N,N,N′,N′-tetraacetate (EDTA) complexes

The d.c. polarographic current-potential curves of Cd(II)-EDTA complexes were examined in the pH range 0.5–10.0, to elucidate the mechanism of their electrode processes and to determine the relevant electrochemical kinetic parameters. It was shown that the first wave observed below pH 3 at ?0.58 to ?0.65 V vs. SCE is the reversible reduction wave of Cd(II) aquo-ion with kinetically-controlled limiting current, and the second wave observed above pH 1.5 at ?0.75 to ?1.21 V vs. SCE corresponds to the simultaneous irreversible reduction of four complex species, CdH₃L⁺, CdH₂L, CdHL^? and CdL^2?, where CdH_pL^(p?2)+ and L^4? denote the protonated complex species with p protons and the unprotonated EDTA ion, respectively. Analysis of the dependence of limiting current on the hydrogen ion concentration led to the conclusion that the preceding reaction determining the behaviour of limiting current is CdH₃L⁺?Cd²⁺+H₃L^? with k₃^d=6.3×10² s^?1 and k₃^f=3.3×10⁶ s^?1M^?1, where k₃^d and k₃^f are the dissociation and formation rate constants, respectively. On the other hand, from analysis of the dependence of half-wave potentials of the second wave on the hydrogen ion concentration, the kinetic parameters of the four complex species were evaluated, and are given in Table 1. Further, it was shown that the cathodic rate constants of these four charge transfer processes at some reference potential together with those of Cd(II)-HEDTA complexes fulfil the linear free energy relationship.