Cationic ruthenium and osmium systems: V. Cationic osmium(II) hydrazine and hydrazone complexes derived from the polymer [OsCl2(COD)]x (COD = cyclo-octa-1,5-diene; x > 2). The crystal structure of [Os(COD(CNBut)2(NH2H:CMe2)2][BPh4]2·(acetone)2

The polymer [OsCl₂(COD)]_x (1; COD = cycloocta-1,5-diene; x > 2) and the appropriate hydrazine have been used to prepare the salts [OsCl(COD)(N₂H₄)₃]BPh₄ (2), [Os(COD)(N₂H₄)₄][BPh₄]₂ (3) and [OsCl(COD)(NH₂NMe₂)₃]PF₆ (4). Treatment of 3 with t-butyl isocyanide produced mer-[Os(CNBu^t)₃(N₂H₄)₃][BPh₄]₂ (5) and trans-[Os(CNBu^t)₄(N₂H₄)₂][BPh₄]₂ (6) from refluxing ethanol and the hydrazone complex [Os(COD)(CNBu^t)₂(NH₂N:CMe₂)₂][BPh₄]₂ (7) from refluxing acetone. Reactions of 3 and L {L = CNxylyl, P(OMe)₃, and P(OMe)₃Ph; xylyl = 2,6-dimethylphenyl} in acetone gave trans-[Os(NH₂N:CMe₂)₂L₄][BPh₄]₂ (8). The crystal structure of [Os(COD)(CNBu^t)₂(NH₂N:CMe₂)₂][BPh₄]₂·(Acetone)₂ (7) has been determined from three-dimensional X-ray counter data and refined to a final R (on F) of 0.090 based on 3014 reflections. The compound crystallizes in the monoclinic space group C2/c with four formula units in a cell of dimensions a 24.60(2), b 13.31(1), c 24.12(2) Å and β 111.51(2)°. The cation has a crystallographically imposed C₂ symmetry, with octahedral coordination of the osmium atom, assuming that the COD ligand occupies two adjacent coordination sites. Coordination of the mutually trans hydrazone ligands to the osmium atom is through the amino-N atoms rather than through the less basic, more sterically hindered, imino-N atoms. relevant bond distances are: Os-N 2.19(2) (mean), Os-C(COD) 2.19(2) and 2.29(2), and Os-C(isocyanide) 1.93(2) (mean) Å.     

Aggregation of Dinuclear Cations [{Au(PR3)}2(μ‐OH)]+ into Dimers Induced by Polyoxometalate (POM) Template Effects

Intercluster compounds, [{(Au{P(p‐XPh)₃})₂(μ‐OH)}₂][α‐SiMo₁₂O₄₀(Au{P(p‐XPh)₃})₂] · nEtOH [X = F ( 1 ), Cl ( 2 )] were synthesized by polyoxometalate (POM)‐mediated clusterization, and were unequivocally characterized by X‐ray crystallography, elemental analysis, thermogravimetric and differential thermal analysis (TG/DTA), Fourier transform infrared (FT‐IR), solid‐state cross‐polarization magic‐angle‐spinning (CPMAS) ³¹P nuclear magnetic resonance (NMR), and solution (¹H, ³¹P{¹H}) NMR spectroscopy. The “dimer‐of‐dinuclear phosphanegold(I) cation”, i.e., [{(Au{P(p‐XPh)₃})₂(μ‐OH)}₂]²⁺ was formed by the self‐assembly of dinuclear phosphanegold(I) cations, i.e., [(Au{P(p‐XPh)₃})₂(μ‐OH)]⁺, through inter‐cationic aurophilic interactions as the crossed‐edge arrangement (or tetrahedral Au₄ structure) for 1 , while as the parallel‐edge arrangement (or rectangular Au₄ structure) for 2 . The latter arrangement was first attained only by assistance of the POM. The POM anions in 1 and 2 contained two mononuclear phosphanegold(I) cations, i.e., [Au{P(p‐XPh)₃}]⁺, linked to the OMo₂ oxygen atoms of edge‐sharing MoO₆ octahedra. In the solution ³¹P{¹H} NMR of 1 and 2 , we observed single signals due to the rapid exchange of the phosphanegold(I) units. This shows that the OMo₂ oxygen atoms of edge‐sharing MoO₆ octahedra in the Keggin POM act as multi‐centered active binding sites for the formation of [{(Au{P(p‐XPh)₃})₂(μ‐OH)}₂]²⁺.     

Synthesis,characterization and monitoring of trans-[Ru{P(OMe)3}4Cl2] by reversed-phase high-performance liquid chromatography and 31P-n.m.r.

P(OMe₃)₃ reacts with RuCl₃ · 3H₂O to produce the complex trans-[Ru{P(OMe)₃}₄Cl₂] from which the complexes trans-[Ru{P(OMe)₃}₄S₂]²⁺ and cis-[Ru{P(OMe)₃}₂S₄]²⁺ (S = Solvent) can be prepared by solvation in neutral and acidic solution, respectively. The aquation takes place with a specific rate of 1.0 × 10^–2 min^–1 (pH = 3.0) and 5.4 × 10^–3 min^–1 (pH 7.0) The trans-[Ru{P(OMe)₃}₄Cl₂] complex has been characterized by elemental analysis; electronic spectra [_max = 408 nm] ( = 1.7 × 10² M^–1 cm^–1), _max = 250 nm ( = 3.5 × 10³ M^–1 cm^–1) and a shoulder at = 280 nm ( 8.3 × 10² M^–1 cm^–1)]; cyclic voltametry ( = 0.75 V versus s.c.e.); HPLC (t _R = 5.7 min); and ³¹P-n.m.r. ( = 131 p.p.m.). In acidic solutions the ³¹P-n.m.r. variations point to a reaction intermediate, characterized as the complex ion trans-[Ru{P(OMe)₃}₄S₂]²⁺ ( = 136 p.p.m.) followed by the formation of the proposed product, cis-[Ru{P(OMe)₃}₂S₄]²⁺ ( = 145 p.p.m.). For this same complex, at pH = 7.0, the results show the formation of the trans-[Ru{P(OMe)₃}₄S₂]²⁺ ( = 136 p.p.m.). The HPLC results for the trans-[Ru{P(OMe)₃}₄Cl₂] complex show that the different species are present at different pH values. In acidic media a less polar species (t _R = 4.3 min) compared with the starting material (t _R = 5.7 min) was formed. At neutral pH (t _R = 4.6 min) the species generated were not modified, however they exhibited different properties from the species obtained at a lower pH.     

Metallabis(phosphonate) als Chelatliganden. I. Synthese einkerniger Nickelbis(phosphonat)–Komplexe mit OHO-Wasserstoffbrücke und entsprechender Alkali-metall-, Ammonium- und Thallium-Verbindungen

Nickelocen reagiert mit Dialkylphosphiten HP(O)(OR)₂ zu den Komplexen C₅H₅Ni[{P(OR)₂O}₂H] ( 1 :R ? Me; 2 :R ? Et), in denen ein sechsgliedriger NiP₂O₂H-Ring mit einer vermutlich symmetrischen OHO-Wasserstoffbrücke vorliegt. Die Umsetzung von 1 mit HBF₄ führt zu C₅H₅Ni[{P(OMe)₂O}₂BF₂] ( 3 ). Mit NH₃ und Thalliumacetylacetonat entstehen aus 1 bzw. 2 die Komplexe [C₅H₅Ni{P(OR)₂O}₂]NH₄ ( 4, 5 ) und [C₅H₅Ni{P(OR)₂O}₂]Tl ( 6, 7 ). Die entsprechenden Alkalimetallverbindungen [C₅H₅Ni{P(OMe)₂O}₂]M ( 8 :M ? Li; 9 :M ? Na) sind ausgehend von C₅H₅Ni[P(OMe)₃][P(O)(OMe)₂] und LiI bzw. NaI zugänglich. C₅H₅Ni[P(OMe)₃][P(O)(OMe)₂] reagiert mit HgI₂ zu C₅H₅Ni[P(OMe)₃]I und [IHg{P(O)(OMe)₂}]₂. Metallabisphosphonates as Chelating Ligands. I. Synthesis of Mononuclear Nickelbisphosphonates Containing a OHO-Hydrogen Bridge and of Corresponding Alkali Metal, Ammonium, and Thallium Compounds Nickelocene reacts with dialkylphosphites HP(O)(OR)₂ to form the complexes C₅H₅Ni[{P(OR)₂O}₂H] ( 1 :R ? Me; 2 :Et) which contain a six-membered NiP₂O₂H ring with a presumably symmetrically OHO-hydrogen bond. The reaction of 1 with HBF₄ leads to C₅H₅Ni?[{P(OMe)₂O}₂BF₂] ( 3 ). The complexes 1 and 2 react with NH₃ and thallium acetylacetonate to give [C₅H₅Ni{P(OR)₂O}₂]NH₄ ( 4, 5 ) and [C₅H₅Ni{P(OR)₂O}₂]Tl ( 6, 7 ), respectively. The corresponding alkali metal compounds [C₅H₅Ni{P(OMe)₂O}₂]M ( 8 :M ? Li; 9 :M ? Na) are formed in the reaction of C₅H₅Ni[P(OMe)₃][P(O)(OMe)₂] with LiI or NaI. With HgI₂, C₅H₅Ni[P(OMe)₃][P(O)(OMe)₂] reacts to yield C₅H₅Ni[P(OMe)₃]I and [IHg{P(O)(OMe)₂}]₂.     

Azodicarbonsäureester und Diazoessigester als Reaktionspartner des Ferriophosphaalkens [Cp*(CO)2FeP=C(Ph)NMe2]

Azodicarboxylates and Diazoacetates as Reactants of the Ferriophosphaalkene [Cp*(CO)₂FeP=C(Ph)NMe₂] Reaction of equimolar amounts of the ferriophosphaalkene [Cp*(CO)₂FeP=C(Ph)NMe₂] ( 1 ) and diethyl azodicarboxylate afforded the complex (C₅Me₄CH₂)(CO)₂Fe ( 3 ) as the result of a cheletropic [1+4] cycloaddition with subsequent transprotonation. The diazoacetates N₂=CHCO₂R ( 8a :=tBu; 8b :Et) and 1 gave rise to the formation of the N‐metallated 1, 2, 3‐diazaphospholes [Cp*(CO)₂Fe‐ ] ( 11a, b ). Compounds 3, 11a and 11b were characterized by means of elemental analyses and spectroscopy (IR, ¹H, ¹³C{¹H}, ³¹P{¹H}‐NMR). The molecular structure of 11a was determined by X‐ray diffraction analysis.     

Ruthenium bidentate phosphine complexes for the coordination and catalytic dehydrogenation of amine- and phosphine-boranes

Addition of the amine–boranes H₃B ? NH₂tBu, H₃B ? NHMe₂ and H₃B ? NH₃ to the cationic ruthenium fragment [Ru(xantphos)(PPh₃)(OH₂)H][BAr^F₄] ( 2 ; xantphos=4,5‐bis(diphenylphosphino)‐9,9‐dimethylxanthene; BAr^F₄=[B{3,5‐(CF₃)₂C₆H₃}₄]^?) affords the η¹‐B? H bound amine–borane complexes [Ru(xantphos)(PPh₃)(H₃B ? NH₂tBu)H][BAr^F₄] ( 5 ), [Ru(xantphos)(PPh₃)(H₃B ? NHMe₂)H][BAr^F₄] ( 6 ) and [Ru(xantphos)(PPh₃)(H₃B ? NH₃)H][BAr^F₄] ( 7 ). The X‐ray crystal structures of 5 and 7 have been determined with [BAr^F₄] and [BPh₄] anions, respectively. Treatment of 2 with H₃B ? PHPh₂ resulted in quite different behaviour, with cleavage of the B? P interaction taking place to generate the structurally characterised bis‐secondary phosphine complex [Ru(xantphos)(PHPh₂)₂H][BPh₄] ( 9 ). The xantphos complexes 2 , 5 and 9 proved to be poor precursors for the catalytic dehydrogenation of H₃B ? NHMe₂. While the dppf species (dppf=1,1′‐bis(diphenylphosphino)ferrocene) [Ru(dppf)(PPh₃)HCl] ( 3 ) and [Ru(dppf)(η⁶‐C₆H₅PPh₂)H][BAr^F₄] ( 4 ) showed better, but still moderate activity, the agostic‐stabilised N‐heterocyclic carbene derivative [Ru(dppf)(ICy)HCl] ( 12 ; ICy=1,3‐dicyclohexylimidazol‐2‐ylidene) proved to be the most efficient catalyst with a turnover number of 76 h^?1 at room temperature.     

Complexes containing phosphorus lignads—161: New phosphinite,phosphonite and phosphite derivatives of ruthenium,osmium and iridium

The complexes [MHCl(CO)(PPh₃)₃] (M = Ru or Os) readily undergo substitution at the site trans to the hydride ligand to afford phosphinite-, phosphonite-, or phosphite-containing products [MHCI(CO)(PPh₃)₂L] [L = P(OR)Ph₂, P(OR)₂Ph or P(OR)₃ respectively; R = Me or Et]. The ruthenium complexes alone undergo further substitution to afford complex cations [RuH(CO)(PPh₃)_nL_4?n]⁺ [n = 2, L = P(OMe)₃; n = 1, L = P(OR)₃; n = 0, L = P(OR)₂Ph or P(OR)Ph₂] which were isolated and characterised as their tetraphenylborate salts. Synthesis of the cationic complexes [IrHL₅][BPh₄]₂ [L = P(OR)₃, R = Me or Et] is also reported. Stereochemical assignments based on NMR data are given, and second order ³¹P and high field ¹H NMR patterns are analysed.     

Vielseitige Koordinationschemie von Vanadium(V): Substitutionsreaktionen,Umlagerungen und Kondensationsreaktionen von Oxovanadium(V)‐Komplexen des tripodalen Sauerstoffliganden LOMe− = [η5‐(C5H5)Co{P(OMe)2(O)}3]−

Multifaceted Coordination Chemistry of Vanadium(V): Substitution, Rearrangement Reactions, and Condensation Reactions of Oxovanadium(V) Complexes of the Tripodal Oxygen Ligand L_OMe^? = [η⁵‐(C₅H₅)Co{P(OMe)₂(O)}₃]^? The octahedral oxovanadium(V) complex [V(O)F₂L_OMe] of the tripodal oxygen ligand L_OMe^? = [η⁵‐(C₅H₅)Co{P(OMe)₂(O)}₃]^? reacts with alcohols and phenol with substitution of one fluoride ligand to form alkoxo complexes [V(O)F(OR)L_OMe], R = Me, Et, i‐Prop, Ph. In the presence of water, however, both fluoride ions are substituted and a complex with the composition VO₂L_OMe can be isolated. The crystal structure shows that the oxo‐bridged trimer [{V(O)(L_OMe)O}₃] was synthesized. In the presence of BF₃ the fluoride ligand in the alkoxo‐complex [V(O)F(OEt)L_OMe] can be exchanged for pyridine to yield [V(O)(OEt)pyL_OMe]BF₄. Analogous attempts to exchange the fluoride ligand for tetrahydrofuran and acetonitrile induces a rearrangement reaction that leads to the vanadium complex [V(O)(L_OMe)₂]BF₄. The crystal structure of this compound has been determined. Its ¹H and ³¹P‐NMR spectra show that it is a highly fluxional vanadium complex at ambient temperature in solution. The two tripodal ligands L_OMe^? coordinate the vanadium centre as bidentate or tridentate ligands. The exchange bidentate/tridentate becomes slow on the NMR time scale below about 200 K.     

Selective and Efficient Cycloisomerization of Alkynols Catalyzed by a New Ruthenium Complex with a Tetradentate Nitrogen–Phosphorus Mixed Ligand

The new ruthenium complex [Ru(N₃P)(OAc)][BPh₄] ( 4 ), in which N₃P is the N,P mixed tetradentate ligand N,N‐bis[(pyridin‐2‐yl)methyl]‐[2‐(diphenylphosphino)phenyl]methanamine was synthesized. The complex was found to be catalytically active for the endo cycloisomerization of alkynols. The catalytic reactions can be used to synthesize five‐, six‐, and seven‐membered endo‐cyclic enol ethers in good to excellent yields. A catalytic cycle involving a vinylidene intermediate was proposed for the catalytic reactions. Treatment of complex 4 with PhC?CH and H₂O gave the alkyl complex [Ru(CH₂Ph)(CO)(N₃P)][BPh₄] ( 30 ), which supports the assumption that the catalytic reactions involve addition of a hydroxyl group to the C?C bond of vinylidene ligands.     

Scandium Reduced Arene Complex: Protonation and Reaction with Azobenzene

The reactivity of the reduced anthracene complex of scandium [Li(thf)₃][Sc{N(tBu)Xy}₂(anth)] ( 2-anth-Li ) (Xy=3,5-Me₂C₆H₃; anth=C₁₄H₁₀²⁻, thf=tetrahydrofuran) toward Brønsted acid [NEt₃H][BPh₄] and azobenzene is reported. While a stepwise protonation of 2-anth-Li with two equivalents of [NEt₃H][BPh₄] afforded the scandium cation [Sc{N(tBu)Xy}₂(thf)₂][BPh₄] ( 3 ), reduction of azobenzene gave a thermolabile, anionic scandium reduced azobenzene complex [Li(thf)][Sc{N(tBu)Xy}₂(η²-PhNNPh)] ( 4 ), which slowly lost one of the anilide ligands to form the neutral scandium azobenzene complex dimer [Sc{N(tBu)Xy}(μ-η²:η²-Ph₂N₂)]₂ ( 5 ). Exposure of 3 to CO₂ produced the scandium carbamate complex [Sc{κ²-O₂CN(tBu)(Xy)}₂][BPh₄] ( 6 ) as a result of CO₂ insertion into the Sc−N bonds. In an attempt to prepare scandium hydrides, the reaction of 3 with the hydride sources LiAlH₄ and Na[BEt₃H] led to the terminal aluminum hydride [AlH{N(tBu)Xy}₂(thf)] ( 7 ) and the scandium n-butoxide [Sc{N(tBu)(Xy)}₂(μ-OnBu)] ( 8 ) after Sc/Al transmetalation and nucleophilic ring-opening of THF, respectively. All reported compounds isolated in moderate to good yields were fully characterized.     

Platinum complexes with diamino-substituted phosphorus ligands: Synthesis,characterization, and their reactivity with a Lewis acid

Reaction of dialkyl- or diaryl-platinum complexes PtR₂(cod) (cod = η², η²-1,5-cyclooctadiene, R = Me, p-tol) with diamino-substituted phosphorus ligands P(NMeCH₂)₂(R′) (R′ = OMe, NEt₂) produced neutral complexes, cis-[Pt(R)₂{P(NMeCH₂)₂(R′)}₂]. On the other hand, reaction of dihalogeno platinum complex PtX₂(cod) (X = Cl, I) with P(NMeCH₂)₂(OMe) yielded a cationic complex [PtX{P(NMeCH₂)₂(OMe)}₃]X. A platinum complex having both methyl and halogeno ligands, PtMeX(cod), reacted with P(NMeCH₂)₂(OMe) to give a cationic methyl complex [PtMe{P(NMeCH₂)₂(OMe)}₃]X, by contrast, it reacted with P(NMeCH₂)₂(NEt₂) to yield a neutral methyl complex [PtMeX{P(NMeCH₂)₂(NEt₂)}₂]. Reaction of [PtMe{P(NMeCH₂)₂(OMe)}₃]X with BF₃·OEt₂ and then NaBPh₄ afforded [PtX{P(NMeCH₂)₂(OMe)}₃]BPh₄, showing preferential Me group abstraction on the Pt center rather than the OMe abstraction on the phosphorus atom, followed by the coordination of X to the Pt center. All new complexes were fully characterized using ¹H, ¹³C{¹H}, and ³¹P{¹H} NMR measurements and elemental analyses. In addition, structures of several complexes were determined by single crystal X-ray diffraction studies.     

Thiosemicarbazonates of Ruthenium(II): Crystal Structures of [Bis(triphenylphosphine)][bis(N‐phenyl‐pyridine‐2‐carbaldehyde Thiosemicarbazonato)]ruthenium(II) and [Bis(diphenylphosphino)butane][bis(salicylaldehyde Thiosemicarbazonato)]ruthenium(II)

Reaction of RuCl₂(PPh₃)₃ with N‐Phenyl‐pyridine‐2‐carbaldehyde thiosemicarbazone (C₅H₄N–C²(H)=N³‐N²H–C¹(=S)N¹HC₆H₅, Hpytsc‐NPh) in presence of Et₃N base led to loss of ‐N²H‐proton and yielded the complex [Ru(pytsc‐NPh)₂(Ph₃P)₂] ( 1 ). Similar reactions of precursor RuCl₂[(p‐tolyl)₃P]₃ with a series of thiosemicarbazone ligands, viz. pyridine‐2‐carbaldehyde thiosemicarbazone (Hpytsc), salicylaldehyde thiosemicarbazone (H₂stsc), and benzaldehyde thiosemicarbazone (Hbtsc), have yielded the complexes, [Ru(pytsc)₂{(p‐tolyl)₃P}₂] ( 2 ), [Ru(Hstsc)₂{(p‐tolyl)₃P}]₂ ( 3 ), and [Ru(btsc)₂{(p‐tolyl)₃P}₂] ( 4 ), respectively. The reactions of precursor Ru₂Cl₄(dppb)₃ {dppb = Ph₂P–(CH₂)₄–PPh₂} with H₂stsc, Hbtsc, furan‐2‐carbaldehyde thiosemicarbazone (Hftsc) and thiophene‐2‐carbaldehyde thiosemicarbazone (Httsc) have formed complexes of the composition, [Ru(Hstsc)₂(dppb)] ( 5 ), [Ru(btsc)₂(dppb)] ( 6 ), [Ru(ftsc)₂(dppb)] ( 7 ), and [Ru(ttsc)₂(dppb)] ( 8 ). The complexes have been characterized by analytical data, IR, NMR (¹H, ³¹P) spectroscopy and X‐ray crystallography ( 1 and 5 ). The proton NMR confirmed loss of –N²H– proton in all the compounds, and ³¹P NMR spectra reveal the presence of equivalent phosphorus atoms in the complexes. In all the compounds, thiosemicarbazone ligands coordinate to the Ru^II atom via hydrazinic nitrogen (N²) and sulfur atoms. The arrangement around each metal atom is distorted octahedral with cis:cis:trans P, P:N, N:S, S dispositions of donor atoms.     

Preparation of Hydride‐Ethylene Complexes of Osmium

Ethylene complexes [OsH(η²‐CH₂=CH₂)L₄]Y ( 1 , 2 ) [L = PPh(OEt)₂, P(OEt)₃; Y = OTf, BPh₄] were prepared by reacting the dihydride OsH₂L₄ first with methyl triflate CH₃OTf and then with ethylene (1 atm). Alternatively, the compound [OsH(η²‐CH₂=CH₂){PPh(OEt)₂}₄]OTf was prepared by allowing the dinitrogen derivative [OsH(N₂){PPh(OEt)₂}₄]OTf to react with ethylene. Acrylonitrile CH₂=C(H)CN reacts with OsH(OTf)L₄ [L = P(OEt)₃] to give the complex [OsH{κ¹‐NCC(H)=CH₂}{P(OEt)₃}₄]BPh₄ ( 3 ). The complexes were characterized spectroscopically (IR and ¹H, ¹³C, ³¹P NMR) and by X‐ray crystal structure determination of the [OsH(η²‐CH₂=CH₂){PPh(OEt)₂}₄]BPh₄ derivative.     

Reactivity with Amines of Bis(cyanamide) and Bis(cyanoguanidine) Complexes of the Iron Triad

Treatment of bis(cyanamide) [M(N≡CNEt₂)₂L₄](BPh₄)₂ and bis(cyanoguanidine) [M{N≡CN(H)C(NH₂)=NH}₂L₄](BPh₄)₂ complexes [M = Fe, Ru, Os; L = P(OEt)₃] with an excess of amine RNH₂ (R = nPr, iPr) affords mixed‐ligand complexes with cyanamide and amine [M(NH₂R)(N≡CNEt₂)L₄](BPh₄)₂ ( 1a – 5a ) and [M(NH₂R){N≡CN(H)C(NH₂)=NH}L₄](BPh₄)₂ ( 1b , 2b ). The complexes were characterized by spectroscopy and X‐ray crystal structure determination of [M(NH₂iPr)(N≡CNEt₂){P(OEt)₃}₄](BPh₄)₂ [M = Ru ( 3a ), Os ( 5a )].     

Reactivity of cationic methyl rhodium(III) complexes cis-[Rh(β-diket)(PPh3)2(CH3)(CH3CN)][BPh4] toward ligands of different character: pyridine, carbon monoxide, and triphenylphosphine

Cationic methyl complex of rhodium(III), cis-[Rh(Acac)(PPh₃)₂(CH₃)(Py)][BPh₄] (1) as a single isomer with Py in the trans to PPh₃ position, is formed upon the reaction of cis-[Rh(Acac)(PPh₃)₂(CH₃)(CH₃CN)][BPh₄] with pyridine in methylene chloride solution.Complex 1 was characterized by elemental analysis and by ³¹P{¹H} and ¹H NMR spectra.Cationic pentacoordinate acetyl complexes, trans-[Rh(Acac)(PPh₃)₂(COCH₃)][BPh₄] (2) and trans-[Rh(BA)(PPh₃)₂(COCH₃)][BPh₄] (3), are prepared by action of carbon monoxide on cis-[Rh(Acac)(PPh₃)₂(CH₃)(CH₃CN)][BPh₄] and cis-[Rh(BA)(PPh₃)₂(CH₃)(CH₃CN)][BPh₄], respectively, in methylene chloride solutions.Complexes 2 and 3 were characterized by elemental analysis and by IR, ³¹P{¹H}, ¹³C{¹H} and ¹H NMR. According to NMR data, 2 and 3 in solution are non-fluxional trigonal bipyramids with β-diketonate and acetyl ligands in the equatorial plane and axial phosphines.In solutions, 2 and 3 gradually isomerize into octahedral methyl carbonyl complexes trans-[Rh(Acac)(PPh₃)₂(CO)(CH₃)][BPh₄] (4) and trans-[Rh(BA)(PPh₃)₂(CO)(CH₃)][BPh₄] (5), respectively.Complexes 4 and 5 were characterized by IR, ³¹P{¹H}, ¹³C{¹H} and ¹H NMR, without isolation.Upon the action of PPh₃ on cis-[Rh(Acac)(PPh₃)₂(CH₃)(CH₃CN)][BPh₄] and cis-[Rh(BA)(PPh₃)₂(CH₃)(CH₃CN)] [BPh₄], reductive elimination of the methyl ligand as a phosphonium salt, [CH₃PPh₃][BPh₄], occurs to give square planar rhodium(I) complexes [Rh(Acac)(PPh₃)₂] and[Rh(BA)(PPh₃)₂], respectively. The reaction products were identified in the reaction mixtures by ³¹P{¹H} and ¹H NMR.     

The Influence of N‐Heterocyclic Carbenes (NHC) on the Reactivity of [Ru(NHC)4H]+ With H2, N2, CO and O2

The five‐coordinate ruthenium N‐heterocyclic carbene (NHC) hydrido complexes [Ru(IiPr₂Me₂)₄H][BAr^F₄] ( 1 ; IiPr₂Me₂=1,3‐diisopropyl‐4,5‐dimethylimidazol‐2‐ylidene; Ar^F=3,5‐(CF₃)₂C₆H₃), [Ru(IEt₂Me₂)₄H][BAr^F₄] ( 2 ; IEt₂Me₂=1,3‐diethyl‐4,5‐dimethylimidazol‐2‐ylidene) and [Ru(IMe₄)₄H][BAr^F₄] ( 3 ; IMe₄=1,3,4,5‐tetramethylimidazol‐2‐ylidene) have been synthesised following reaction of [Ru(PPh₃)₃HCl] with 4–8 equivalents of the free carbenes at ambient temperature. Complexes 1 – 3 have been structurally characterised and show square pyramidal geometries with apical hydride ligands. In both dichloromethane or pyridine solution, 1 and 2 display very low frequency hydride signals at about δ ?41. The tetramethyl carbene complex 3 exhibits a similar chemical shift in toluene, but shows a higher frequency signal in acetonitrile arising from the solvent adduct [Ru(IMe₄)₄(MeCN)H][BAr^F₄], 4 . The reactivity of 1 – 3 towards H₂ and N₂ depends on the size of the N‐substituent of the NHC ligand. Thus, 1 is unreactive towards both gases, 2 reacts with both H₂ and N₂ only at low temperature and incompletely, while 3 affords [Ru(IMe₄)₄(η²‐H₂)H][BAr^F₄] ( 7 ) and [Ru(IMe₄)₄(N₂)H][BAr^F₄] ( 8 ) in quantitative yield at room temperature. CO shows no selectivity, reacting with 1 – 3 to give [Ru(NHC)₄(CO)H][BAr^F₄] ( 9 – 11 ). Addition of O₂ to solutions of 2 and 3 leads to rapid oxidation, from which the Ru^III species [Ru(NHC)₄(OH)₂][BAr^F₄] and the Ru^IV oxo chlorido complex [Ru(IEt₂Me₂)₄(O)Cl][BAr^F₄] were isolated. DFT calculations reproduce the greater ability of 3 to bind small molecules and show relative binding strengths that follow the trend CO ? O₂ > N₂ > H₂.     

Gold(I) and Silver(I) Complexes of Diphosphacyclobutadiene Cobaltate Sandwich Anions

The synthesis and structural characterization of the first coordination compounds of bis(diphosphacyclobutadiene) cobaltate anions [M(P₂C₂R₂)₂]^? is described. Reactions of the new potassium salts [K(thf)₃{Co(η⁴‐P₂C₂tPent₂)₂}] ( 1 ) and [K(thf)₄{Co(η⁴‐P₂C₂Ad₂)₂}] ( 2 ) with [AuCl(tht)] (tht=tetrahydrothiophene), [AuCl(PPh₃)] and Ag[SbF₆] afforded the complexes [Au{Co(P₂C₂tPent₂)₂}(PMe₃)₂] ( 3 ), [Au{Co(P₂C₂Ad₂)₂}]_x ( 4 ), [Ag{Co(P₂C₂Ad₂)₂}]_x ( 5 ), [Au(PMe₃)₄][Au{Co(P₂C₂Ad₂)₂}₂] ( 6 ), [K([18]crown‐6)(thf)₂][Au{Co(P₂C₂Ad₂)₂}₂] ( 7 ), and [K([18]crown‐6)(thf)₂][M{Co(P₂C₂Ad₂)₂}₂] ( 8 : M=Au 9 : M=Ag) in moderate yields. The molecular structures of 2 and 3 , and 6 – 9 were elucidated by X‐ray crystallography. Complexes 4 – 9 were thoroughly characterized by ³¹P and ¹³C solid state NMR spectroscopy. The complexes [Au{Co(P₂C₂Ad₂)₂}]_x ( 4 ) and [Ag{Co(P₂C₂Ad₂)₂}]_x ( 5 ) exist as coordination polymers in the solid state. The linking mode between the monomeric units in the polymers is deduced. The soluble complexes 1 – 3 , 6 , and 7 were studied by multinuclear ¹H‐, ³¹P{¹H}‐, and ¹³C{¹H} NMR spectroscopy in solution. Variable temperature NMR measurements of 3 and 6 in deuterated THF reveal the formation of equilibria between the ionic species [Au(PMe₃)₄]⁺, [Au(PMe₃)₂]⁺, [Co(P₂C₂R₂)₂]^?, and [Au{Co(P₂C₂R₂)₂}₂]^? (R=tPent and Ad).     

Five-Membered Ruthenacycles: Ligand-Assisted Alkyne Insertion into 1,3-N,S-Chelated Ruthenium Borate Species

Building upon previous work, the chemistry of [(η⁶-p-cymene)Ru{P(OMe)₂OR}Cl₂], (R=H or Me) has been extended with [H₂B(mbz)₂]⁻ (mbz=2-mercaptobenzothiazolyl) using different Ru precursors and borate ligands. As a result, a series of 1,3-N,S-chelated ruthenium borate complexes, for example, [(κ²-N,S-L)PR₃Ru{κ³-H,S,S’−H₂B(L)₂}], ( 2 a – d and 2 a’ – d’ ; R=Ph, Cy, OMe or OPh and L=C₅H₄NS or C₇H₄NS₂) and [Ru{κ³-H,S,S’-H₂B(L)₂}₂], ( 3 : L=C₅H₄NS, 3’ : L=C₇H₄NS₂) were isolated upon treatment of [(η⁶-p-cymene)RuCl₂PR₃], 1 a – d (R=Ph, Cy, OMe or OPh) with [H₂B(mp)₂]⁻ or [H₂B(mbz)₂]⁻ ligands (mp=2-mercaptopyridyl). All the Ru borate complexes, 2 a – d and 2 a’ – d’ are stabilized by phosphine/phosphite and hemilabile N,S-chelating ligands. Treatment of these Ru borate species, 2 a’ – c’ with various terminal alkynes yielded two different types of five-membered ruthenacycle species, namely [PR₃{C₇H₄S₂-(E)-N-C=CH(R ’ )}Ru{κ³-H,S,S ’ −H₂B(L)₂}], ( 4 – 4’ ; R=Ph and R ’ =CO₂Me or C₆H₄NO₂; L=C₇H₄NS₂) and [PR₃{C₇H₄NS-(E)-S-C=CH(R ’ )}Ru{κ³-H,S,S ’ −H₂B(L)₂}], ( 5 – 5’ , 6 and 7 ; R=Ph, Cy or OMe and R ’ =CO₂Me or C₆H₄NO₂; L=C₇H₄NS₂). All these five-membered ruthenacycle species contain an exocyclic C=C moiety, presumably formed by the insertion of a terminal alkyne into the Ru−N and Ru−S bonds. The new species have been characterized spectroscopically and the structures were further confirmed by single-crystal X-ray diffraction analysis. Theoretical studies and chemical-bonding analyses established that charge transfer occurs from phosphorus to ruthenium center following the trend PCy₃<PPh₃<P(OPh)₃<P(OMe)₃.     

Schiff base complexes of ruthenium(II) with tridentateN-methyl-S-methyldithiocarbazate ligands

Summary Schiff bases (HL) produced by the condensation ofN-methyl-S-methyldithiocarbazate with -diketones and aromatic aldehydes or ketones react with [RuHClCO(PPh₃)₃] to yield hexacoordinated complexes of the type [RuClCO(PPh₃)₂(L)]. These Schiff bases react with [RuCl₂{P(OR)₃}₄] in 11 molar ratio to yield [RuCl{P(OR)₃}₂(L)] in which L is a tridentate. The chlorine atom in the complex can be removed in coordinating solvents in the presence of anions such as [BPh₄]^– to give cationic complexes. Bis chelate complexes, [Ru{P(OR)₃}₂(L)₂] are prepared from 12 molar proportions of the reactants. These complexes were characterised by elemental analyses, i.r.,¹H n.m.r., u.v. and conductivity studies.NCL Communication No. 4224.     

Synthesis and Characterization of trans‐PdII Trimethylsilylchalcogenolates

The trans‐bis(trimethylsilyl)chalcogenolate palladium complexes, trans‐[Pd(ESiMe₃)₂(PnBu₃)₂] [E = S ( 1 ) and Se ( 2 )] were synthesized in good yields and high purity by reacting trans‐[PdCl₂(PBu₃)₂] with LiESiMe₃ (E = S, Se), respectively. These complexes were characterized by ¹H, ¹³C{¹H}, ³¹P{¹H} (and ⁷⁷Se{¹H}) NMR spectroscopy and single‐crystal X‐ray analysis. The reaction of 2 with propionyl chloride led to the formation of trans‐[Pd(SeC(O)CH₂CH₃)₂(PnBu₃)₂] ( 3 ), a trans‐bis(selenocarboxylato) palladium complex and thus established a new method for the formation of this type of complex. Complex 3 was characterized by ¹H, ¹³C{¹H}, ³¹P{¹H} and ⁷⁷Se{¹H} NMR spectroscopy and a single‐crystal X‐ray structure analysis.