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.     

Reactivity of the tetrahydroborate copper(I) complexes [(PR3)2Cu(η2-BH4)] (R = Ph,Cy) toward CO2, COS,and SCNPh

CO₂, COS, and SCNPh react under very mild conditions with the copper(I)-tetrahydroborate complexes [(PR₃)₂Cu(η²-BH₄)] (R = Ph, Cy); CO₂ and COS give the complexes [(PR₃)₂Cu(η²-O₂CH)] and [(PR₃)₂Cu(η²-OSCH)] respectively, whereas SCNPh gives the η²-dithiocarbamate complexes [(PR₃)₂Cu-(η²-S₂CNHPh)]. Addition of PPh₃ under CO₂ to solutions of [(PPh₃)₂Cu-(η²-BH₄)] gives [(PPh₃)₃Cu(η¹-O₂CH)] while addition of PPh₃ and NBu₄ClO₄ under CO₂ gives [(PPh₃)₃Cu(η-O₂CH)Cu(PPh₃)₃] ClO₄.     

Catalytic and anticancer activities of sawhorse-type diruthenium tetracarbonyl complexes derived from fluorinated fatty acids

The reaction of fluorinated fatty acids, perfluorobutyric acid (C₃F₇CO₂H), and perfluorododecanoic acid (C₁₁F₂₃CO₂H), with dodecacarbonyltriruthenium (Ru₃(CO)₁₂) under reflux in tetrahydrofuran, followed by addition of two-electron donors (L) such as pyridine, 1,3,5-triaza-7-phosphatricyclo[3.3.1.1]decane, or triphenylphosphine, gives stable diruthenium complexes Ru₂(CO)₄(μ₂-η²-O₂CC₃F₇)₂(L)₂ (1a, L?=?C₅H₅N; 1b, L?=?PTA; 1c, L?=?PPh₃) and Ru₂(CO)₄(μ₂-η²-O₂CC₁₁F₂₃)₂(L)₂ (2a, L?=?C₅H₅N; 2b, L?=?PTA; 2c, L?=?PPh₃). The catalytic activity of the complexes for hydrogenation of styrene under supercritical carbon dioxide has been assessed and compared to the analogous triphenylphosphine complexes with non-fluorinated carboxylato groups Ru₂(CO)₄(μ₂-η²-O₂CC₃H₇)₂(PPh₃)₂ (3) and Ru₂(CO)₄(μ₂-η²-O₂CC₁₁H₂₃)₂(PPh₃)₂ (4). In addition, the cytotoxicities of the fluorinated complexes 1 were also evaluated on several human cancer cell lines (A2780, A549, Me300, HeLa). The complexes appear to be moderately cytotoxic, showing greater activity on the Me300 melanoma cells. Single-crystal X-ray structure analyses of 1a and 3 show the typical sawhorse-type arrangement of the diruthenium tetracarbonyl backbone with two bridging carboxylates and two terminal ligands occupying the axial positions.     

Effect of PDI ligand binding pattern on the electrocatalytic activity of two Ru(II) complexes for CO2 reduction

The electrochemical properties of two complexes, [Ru^II(η³-(N,N,N)-^OMePDI)Cl₂(PPh₃)]⁰ ( 1 ) and [Ru^II(η²-(C,N)-^OMePDI-H)Cl (PPh₃)₂]⁰ ( 2 ), were studied. In octahedral complex 1 , bis(imino)pyridine (PDI) is a tridentate η³-N,N,N-coordinated ligand, whereas in trigonal-bipyramidal complex 2 , the deprotonated PDI ligand adopts the unusual bidentate binding mode η²-C,N to coordinate to the central Ru(II) ion. Bulk electrolysis in two electrolyte solutions of acetonitrile (MeCN) and tetrahydrofuran (THF) suggests that complexes 1 and 2 have very different electrocatalytic CO₂ reduction activities. In MeCN solution, complex 1 can selectively electrocatalytic CO₂ reduction to CO with a Faradaic efficiency of about 50% and a turnover frequency (TOF) of 4.4 s⁻¹, whereas complex 2 can perform electrocatalytic of CO₂ reduction with a Faraday efficiency of ~22% and a TOF of 0.3 S⁻¹. The electrocatalytic CO₂ reduction selectivity and activity of the two complexes are poor when the solvent is changed to THF. Combined with the results of the density functional theory calculation, we propose that the binding pattern of the redox-active ligand ^OMePDI has a significant effect on the electrocatalytic activity for the two Ru(II)PDI complexes.     

On the Role of Alkali-Metal-Like Superatom Al12P in Reduction and Conversion of Carbon Dioxide

Developing efficient catalysts for the conversion of CO₂ into fuels and value-added chemicals is of great significance to relieve the growing energy crisis and global warming. With the assistance of DFT calculations, it was found that, different from Al₁₂X (X=Be, Al, and C), the alkali-metal-like superatom Al₁₂P prefers to combine with CO₂ via a bidentate double oxygen coordination, yielding a stable Al₁₂P(η²-O₂C) complex containing an activated radical anion of CO₂ (i.e., CO₂^.−). Thereby, this compound could not only participate in the subsequent cycloaddition reaction with propylene oxide but also initiate the radical reaction with hydrogen gas to form high-value chemicals, revealing that Al₁₂P can play an important role in catalyzing these conversion reactions. Considering that Al₁₂P has been produced in laboratory and is capable of absorbing visible light to drive the activation and transformation of CO₂, it is anticipated that this work could guide the discovery of additional superatom catalysts for CO₂ transformation and open up a new research field of superatom catalysis.     

Photosensitive Tin Sulfur Dioxide Complexes with Unexpected Bonding Modes

Infrared spectra of the matrix-isolated Sn(η²-O₂S), Sn(η²-OSO), Sn(η²-O₂S)(η¹-OSO), Sn(η²-O₂S)_2, OSn₂(η²-SO), and Sn(μ₂-O₂)SnS molecules were observed following laser-ablated Sn atom reactions with SO₂ during condensation in solid argon. The assignments for the major vibrational modes were confirmed by appropriate S¹⁸O₂ and ³⁴SO₂ isotopic shifts and density functional vibrational frequency calculations (B3LYP and BPW91). Interestingly, the mononuclear complexes are interconvertible; that is, irradiation induces the isomerization of Sn(η²-O₂S) and Sn(η²-O₂S)(η¹-OSO) to Sn(η²-OSO) and Sn(η²-O₂S)₂, respectively, and vice versa on annealing. However, there is no evidence of isomerization reaction in between the binuclear molecules OSn₂(η²-SO) and Sn(μ₂-O₂)SnS. Bonding in these products is discussed, and the electronic structure changes associated with different bonding types are revealed, which is crucial for the observed photochemical reactions.     

Migration of hydrogen from metal to alkene promoted by dioxygen addition. Oxygen atom transfer from a cis-(alkyl)(η2-dioxygen) complex of rhodium to organic and inorganic substrates

The novel cis-(σ-alkyl)(η²-O₂) complexes of rhodium [(THF)(EtOH)Naμ-EtOH₂μ-(CO₂R)CH₂CH(CO₂R)Rh(η²-O₂)(triphos)₂Na(EtOH)(THF)][BPh₄]₂·2EtOH (R = Me,3; Et,4) have been synthesized by reaction of dioxygen with the hydrides (triphos)(RhH(η²-alkene) followed by NaBPh₄ addition (alkene = dimethyl fumarate,1; diethyl fumarate,2) (triphos = MeC(CH₂PPh₂)₃). The structure of4 has been determined by X-ray diffraction. Oxygen atom transfer reactions from the η²-O₂ complexes to various inorganic and organic substrates have been studied.     

Über die natur der übergangsmetall-kohlenstoff-σ-bindung: IX. Über die darstellung und charakterisierung von η5-cyclopentadienyl-triphenylphosphin-nickel-η1-thioanisolyl und seine thermische zersetzung in nickelthiophenolatokomplexe

The reaction of Cp(PPh₃)NiCl (Cp = η⁵-C₅H₅) with PhSCH₂Li gives Cp(PPh₃)Ni(η¹-CH₂SPh) (I), which has been isolated as green crystals and characterized by elemental analysis, magnetic measurement, ¹H NMR and mass spectroscopic investigations and by protolysis to form PhSCH₃. Cp₂Ni also reacts with PhSCH₂Li in the presence of PPh₃ to give I containing 5–10% of Cp(PPh₃)NiSPh (II) and about 1% of [CpNiSPh]₂ (III) as impurities. In the absence of PPh₃, III is formed, with the release of ethylene and cyclopropane, even at a temperature of ?20°C. For comparison, II has been synthesized from Cp₂Ni, PPh₃ and LiSPh and from the reaction of III with PPh₃.I decomposes in boiling benzene to give II (ca. 33%) and III (ca. 13%). The conversion of the thioanisolyl into thiophenolato complexes can be understood on assuming that {CpNi(η²-CH₂SPh)} is formed as an unstable intermediate.     

Excellent electrocatalytic activity of benzil for direct reduction of CO_2 as well as indirect reduction of pyridine:A kinetic view of the electrocarboxylation process

Benzil,1,2-diphenylethane-1,2-dione, was used as an excellent electrocatalyst for reduction of carbon dioxide, CO_2. The reduction overpotential of CO_2 was reduced about 900 m V in the presence of a benzil mediator. The chemical reaction of the product of the electrocatalytic reduction of CO_2,(activated CO_2,CO_2~(·-)) with pyridine at a glassy carbon electrode, GCE, surface and in an acetonitrile-But_4NClO_4 solution was investigated by cyclic voltammetry, chronoamperometry and controlled potential coulometry.By chronoamperometry, the catalytic rate constant, k, for the electron transfer between benzil and CO_2 was obtained as 8.1 ± 0.4 M~(-1)s~(-1). The results indicate that pyridine has a strong interaction with the activated CO_2. The coulometry method was used to obtain the product of the pyridine chemical reaction with CO_2~(·-). The spectral characterizations of FTIR,~1H and ~(13)C NMR of the coulometry experiment product proved that the pyridine anion radical, Py~(·-), was carboxylated by CO_2~(·-), and isonicotinic acid is the final major product.     

A novel synthesis of 4-alkyl-4-(4-methoxyphenyl)cyclohex-2-en-1-ones and the Sceletium alkaloid,o-methyljoubertiamine.

The dianion formed by reduction of (η⁶:η⁶-4,4′-dimethoxybiphenyl)[Cr(CO)₃]₂ reacts with electrophiles such as methyl or ethyl triflate or allyl tosylate at −78 °C followed by CF₃CO₂H and I₂ to form 4-alkyl-4-(4-methoxyphenyl)cyclohex-2-en-1-ones.     

Di(tert-butyl)diazomethan: Thermische Zersetzung und Einelektronen-Redox-Reaktionen

Di(tert-butyl)diazomethane: Thermal Decomposition and One-Electron Redox Reactions. Di(tert-butyl)diazomethane is a potential precursor for the still unknown, presumably sterically overcrowded tetrakis(tert-butyl)ethane and, therefore, re-investigated. Its (Hel) photoelectron spectrum exhibits a low first vertical ionization energy of only 7.45 eV. Based on the ionization pattern, both the thermal decomposition above 600 K under nearly unimolecular conditions as well as the N₂ elimination at the surface of contacts, [Ni_x/C]_∞, [Rh₄(CO)₁₂/SiO₂]_∞, [Rh_x/SiO₂]_∞, and [Ag₂CO₃]_∞ are analyzed in a flow-system. Heterogeneously catalyzed, N₂ is split off already at room temperature, but in contrast to results for sterically less shielded diazo compounds, no dimer is formed, and only mixtures of known di(tert-butyl)carbene-isomerization products are isolated. Cyclic voltammetry at 233 K using a glassy carbon electrode proves a reversible oxidation followed by N₂ elimination at higher temperatures and an irreversible reduction. On chemical oxidation, however, no paramagnetic species can be detected, whereas chemical reduction at a potassium metal mirror in a THF solution containing (2.2.2)cryptand, yields the radical anion characterized by ESR spectroscopy. Without a cation-chelating ligand, the radical anion of a hitherto unknown dimer, ((CH₃)₃C)₂C?N? N?N? N?C(C(CH₃)₃) ₂' ^?, is generated, which dissociates at higher temperature, forming ((CH₃)₃C)₂?N₂' ^?. This one-electron reduction product of di(tert-butyl)diazomethane can also be detected after quickly warming up a solution containing presumably the radical anion of the triphenylphosphane adduct ((CH₃)₃C)₂C?N? N? PPh₃' ^?. In one of these reduction reactions, a N₂ elimination is observed.     

Chemistry of Fischer-type rhenacyclobutadiene complexes. II. Reactions with alkynes and sulfonium ylides, and rearrangements induced by nitriles and pyridine

Further investigations into the chemistry of the rhenacyclobutadiene complexes (CO)₄Re(η²-C(R)C(CO₂Me)C(X)) (1: R=Me, X=OEt (1a), O(CH₂)₃CCH (1b), NEt₂ (1c); R=CHEt₂, X=OEt (1d); R=Ph, X=OEt (1e)) are reported. Reactions of 1 with alkynes at reflux temperature of toluene and at ambient temperature either under photochemical conditions or in the presence of PdO yield ring-substituted η⁵-cyclopentadienylrhenium tricarbonyl complexes, 2. The symmetrical alkynes R^′CCR^′ (R^′=Ph, Me, CO₂Me) afford the pentasubstituted complexes (η⁵-C₅(Me)(CO₂Me)(OEt)(Ph)(Ph))Re(CO)₃ (2d), (η⁵-C₅(Me)(CO₂Me)(OEt)(Me)(Me))Re(CO)₃ (2e), (η⁵-C₅(Me)(CO₂Me)(OEt)(CO₂Me)(CO₂Me))Re(CO)₃ (2f), and (η⁵-C₅(Me)(CO₂Me)(NEt₂)(CO₂Me)(CO₂Me))Re(CO)₃ (2i) on reaction with the appropriate 1, whereas the unsymmetrical alkynes R^′CCR″ (R^′=Ph; R″=H, Me) give either only one, (η⁵-C₅(Me)(CO₂Me)(OEt)(Ph)H)Re(CO)₃ (2a)), or both, (η⁵-C₅(Me)(CO₂Me) (OEt)(Ph)(Me))Re(CO)₃ (2b) and (η⁵-C₅(Me)(CO₂Me)(OEt)(Me)(Ph))Re(CO)₃ (2c), (η⁵-C₅(Ph)(CO₂Me)(OEt)(Ph)H)Re(CO)₃ (2g) and (η⁵-C₅(Ph)(CO₂Me)(OEt)(H)(Ph))Re(CO)₃ (2h), of the possible products of [3 + 2] cycloaddition of alkyne to η²-C(R)C(CO₂Me)C(X). Thermolysis of (CO)₄Re(η²-C(Me)C(CO₂Me)C(O(CH₂)₃CCH)) (1b) containing a pendant alkynyl group proceeds to (η⁵-C₅(Me)(CO₂Me)(O(CH₂)₃)H)Re(CO)₃ (2j), a η⁵-cyclopentadienyl-dihydropyran fused-ring product. Competition experiments showed that each of PhCCH and MeO₂CCCCO₂Me reacts faster than PhCCPh with 1a. The results with unsymmetrical alkynes are rationalized by steric properties of substituents at the CC and ReC bonds and by a preference of ReC(Me) over ReC(OEt) to undergo alkyne insertion. A mechanism is proposed that involves substitution of a trans CO by alkyne in 1, insertion of alkyne into ReC bond to give a rhenabenzene intermediate, and collapse of the latter to 2. Complexes 1a and 1d undergo rearrangement in MeCN at reflux temperature to give rhenafuran-like products, (CO)₄Re(κ²-OC(OMe)C(CHCR₂)C(OEt)) (R=H (3a) or Et (3b)). The reaction of 1d also proceeds in EtCN, PhCN, and t-BuCN at comparable temperature, but is slower (especially in t-BuCN) than in MeCN. In pyridine at reflux temperature, 1a undergoes a similar rearrangement, with CO substitution, to give (CO)₃(py)Re(κ²-OC(OMe)C(CHCEt₂)C(OEt)) (4). A mechanism is proposed for these reactions. The sulfonium ylides Me₂SCHC(O)Ph and Me₂SC(CN)₂ (Me₂SCRR^′) react with 1a in acetonitrile at reflux temperature by nucleophilic addition of the ylide to the ReC(Me) carbon, loss of Me₂S, and rearrangement to a rhenafuran-type structure to yield (CO)₄Re(κ²-OC(OMe)C(C(Me)CRR^′)C(OEt)) (R=H, R^′=C(O)Ph (5a); R=R^′CN (5b)). All new compounds were characterized by a combination of elemental analysis, mass spectrometry, and IR and NMR spectroscopy.     

Reactions of a phosphido-bridged unsymmetrical diiron complex (η-C5Me5)Fe2(CO)4(μ-CO)(μ-PPh2) with various alkynes

A phosphido-bridged unsymmetrical diiron complex (η⁵-C₅Me₅)Fe₂(CO)₄(μ-CO)(μ-PPh₂) (1) was synthesized by a new convenient method; photo-dissociation of a CO ligand from (η⁵-C₅Me₅)Fe₂(CO)₆(μ-PPh₂) (2) that was prepared by the reaction of Li[Fe(CO)₄PPh₂] with (η⁵-C₅Me₅)Fe(CO)₂I. The reactivity of 1 toward various alkynes was studied. The reaction of 1 with ^tBuCCH gave a 1:1 mixture of two isomeric complexes (η⁵-C₅Me₅)Fe₂(CO)₃(μ-PPh₂)[μ-CHC(^tBu)C(O)] (3) containing a ketoalkenyl ligand. The reactions of 1 with other terminal alkynes RCCH (R=H, CO₂Me, Ph) afforded complexes incorporating one or two molecules of alkynes and a carbonyl group. The principal products were dinuclear complexes bridged by a new phosphinoketoalkenyl ligand, (η⁵-C₅Me₅)Fe₂(CO)₃(μ-CO)[μ-CR¹CR²C(O)PPh₂] (4a: R¹=H, R²=H; 4b: R¹=CO₂Me, R²=H; 4c: R¹=H, R²=Ph). In the cases of alkynes RCCH (R=H, CO₂Me), dinuclear complexes having a new ligand composed of two molecules of alkynes, a carbonyl group, and a phosphido group; i.e. (η⁵-C₅Me₅)Fe₂(CO)₃[μ-CRCHCHCRC(O)PPh₂] (5a: R=H; 5b: R=CO₂Me), were also obtained. In all cases, mononuclear complexes, (η⁵-C₅Me₅)Fe(CO)[CR¹CR²C(O)PPh₂] (6a: R¹=H, R²=H; 6b: R¹=H, R²=CO₂Me; 6c: R¹=H, R²=Ph) were isolated in low yields. The structures of 1, 4c, 5b, and 6a were confirmed by X-ray crystallography. The detailed structures of the products and plausible reaction mechanisms are discussed.     

Palladium(II) compounds with planar chirality. X-Ray crystal structures of (+)-(R)-[{(η5-C5H4)–CHN–CH(Me)–C10H7}Fe(η5-C5H5)] and (+)-(Rp,R)-[Pd{[(Et–CC–Et)2(η5-C5H3)–CHN–CH(Me)–C10H7]Fe(η5-C5H5)}Cl]

A wide variety of planar chiral cyclopalladated compounds of general formulae [Pd{[(η⁵-C₅H₃)–CHN–CH(Me)–C₁₀H₇]Fe(η⁵-C₅H₅)}Cl(L)] (with L=py-d₅ or PPh₃), [Pd{[(η⁵-C₅H₃)–CHN–CH(Me)–C₁₀H₇]Fe(η⁵-C₅H₅)}(acac)] or [Pd{[(R¹–CC–R²)₂(η⁵-C₅H₃)–CHN–CH(Me)–C₁₀H₇]Fe(η⁵-C₅H₅)}Cl] (with R¹=R²=Et; R¹=Me, R²=Ph; R¹=H, R²=Ph; R¹=R²=Ph; R¹=R²=CO₂Me or R¹=CO₂Et, R²=Ph) are reported. The diastereomers {(R_p,R) and (S_p,R)} of these compounds have been isolated by either column chromatography or fractional crystallization. The free ligand (R)-(+)-[{(η⁵-C₅H₄)–CHN–CH(Me)–C₁₀H₇}Fe(η⁵–C₅H₅)] (1) and compound (+)-(R_p,R)-[Pd{[(Et–CC–Et)₂(η⁵-C₅H₃)–CHN–CH(Me)–C₁₀H₇]Fe(η⁵-C₅H₅)}Cl] (7a) have also been characterized by X-ray diffraction. Electrochemical studies based on cyclic voltammetries of all the compounds are also reported.     

Synthesis and properties of carboxy-substituted half-sandwich ruthenium complexes with chelating bisphosphine ligands (η-C5H4CO2H)Ru(η-L)X (X = I, H)

Several Ru(II) complexes (η⁵-C₅H₄CO₂H)Ru(η²-L)I have been prepared by the hydrolysis of the ester linkage in (η⁵-C₅H₄CO₂t-Bu)Ru(η²-L)Cl with trimethylsilyl iodide. The hydrides (η⁵-C₅H₄CO₂H)Ru(η²-L)H may be prepared by reduction of the iodide complexes in KOH/MeOH solutions followed by acidification. Complexes with several chelating bisphosphine ligands have been prepared in this way. The carboxylate anions [(η⁵-C₅H₄CO₂)Ru(η²-L)H]⁻ are readily protonated by weak acids to give the carboxyCp complexes. The pK_a of the carboxy proton of (η⁵-C₅H₄CO₂H)Ru(dppe)H (dppe = 1,2-bis(diphenylphosphino)ethane) is 11.3 in DMSO. Protonation of the neutral hydride complex (η⁵-C₅H₄CO₂H)Ru(dppf)H gives the cationic dihydride (η⁵-C₅H₄CO₂H)Ru(dppf)H⁺₂; the dihydride structure has been confirmed by measuring the T₁ of its ¹H NMR hydride resonance over a range of temperatures. The oxidations of the halide complexes (η⁵-C₅H₄CO₂H)Ru(dppf)I and (η⁵-C₅H₄CO₂t-Bu)Ru(dppf)Cl (dppf = 1,1′-bis(diphenylphosphino)ferrocene) have been studied by cyclic voltammetry.     

Synthesis and characterization of complexes η5,η5-(CO)3Mn(C5H4-C5H4)(CO)2Fe-η1,η5-C5H4Mn(CO)3 and μ-(C≡C)[C5H4(CO)2Fe-η1,η5-C5H4Mn(CO)3]2

The complex η⁵,η⁵-(CO)₃Mn(C₅H₄-C₅H₄)(CO)₂Fe-η¹,η⁵-C₅H₄Mn(CO)₃ was synthesized by the reaction of η⁵-Cp(CO)₂Fe-η¹,η⁵-C₅H₄Mn(CO)₃ with BuⁿLi (THF, ?78 °C) and then with anhydrous CuCl₂. The complex μ-(C≡C)[C₅H₄(CO)₂Fe-η¹,η⁵-C₅H₄Mn(CO)₃]₂ was prepared by the reaction of η⁵-IC₅H₄(CO)₂Fe-η¹,η⁵-C₅H₄Mn(CO)₃ with Me₃SnC≡CSnMe₃ (2:1) in the presence of Pd(MeCN)₂Cl₂.     

Syntheses,spectroscopy, and X-ray structures of 3-{(R)-(Ar)-ethylimino}-1,3-dihydro-indol-2-one (Ar = Ph,MeOC6H4, BrC6H4, 1-naphthyl) and [Rh(η4-cod){3-((R)-(Ar)-ethylimino)-3H-indol-2-olato}]

Condensation of 1H-indole-2,3-dione (isatin) with (R)-(Ar)-ethylamines gives enantiopure Schiff bases, 3-{(R)-(Ar)-ethylimino}-1,3-dihydro-indol-2-one (HL) {Ar?=?Ph (HL1), 2-MeOC₆H₄ (HL2), 4-MeOC₆H₄ (HL3), 4-BrC₆H₄ (HL4), and 1-naphthyl (HL5)}. The Schiff bases readily coordinate to [Rh(μ-O₂CMe)(η⁴-cod)]₂ (cod?=?1,5-cyclooctadiene) to give mononuclear [Rh(η⁴-cod){3-((R)-(Ar)-ethylimino)-3H-indol-2-olato}] {Ar?=?Ph (1), 4-MeOC₆H₄ (2), and 4-BrC₆H₄ (3)}, respectively. The Schiff bases and complexes have been fully characterized by IR, UV-Vis, ¹H-NMR, mass, and circular dichroism (CD) spectrometry. Polarimetry and CD measurements show the enantiopurity of the Schiff bases as well as the complexes. ¹H NMR measurements reveal slow conversion of the lactam to the enol form of the Schiff bases in solution. In the solid state the lactam form dominates as shown by crystal structures of HL1 and HL4. While gross structural features of both are similar, the molecules differ significantly in the relative orientations of the aryl and lactam rings. The difference is mostly rotation about the N2–C9 bond with different C8–N2–C9–C11 torsion angle of +89.77(12)° for HL1 and C2–N2–C9–C11 of +106.8(3)° for HL4.     

Thiocarbonyl complexes of ruthenium(II). Synthesis of RuCl2(CS)(H2O)(PPh3)2 and RuHCl(CS)(PPh3)3

A high-yield synthesis of trans-RuCl₂(CS)(H₂O)(PPh₃)₂ from RuCl₂(PPh₃)₃ and CS₂ is described. The coordinated water molecule is labile, and introduction of CNR (R  p-toyl or p-chlorophenyl) leads to yellow trans-RuCl₂(CS)(CNR)(PPh₃)₂, which isomerises thermally to colourless cis-RuCl₂(CS)(CNR)(PPh₃)₂. Reaction of AgClO₄ with cis-RuCl₂(CS)(CNR)(PPh₃)₂ gives [RuCl(CS)(CNR)(H₂O)(PPh₃)₂]⁺, from which [RuCl(CS)(CO)(CNR)(PPh₃)₂]⁺ and [RuCl(CS)(CNR)₂(PPh₃)₂]⁺ are derived. Reaction of trans-RuCl₂(CS)(H₂O)(PPh₃)₂ with sodium formate gives Ru(η²-O₂CH)Cl(CS)(PPh₃)₂, which undergoes decarboxylation in the presence of (PPh₃) to give RuHCl(CS)(PPh₃)₃. Ru(η²-O₂CH)H(CS)(PPh₃)₂ and Ru(η²-O₂CMe)-H(CS)(PPh₃)₂ are also described.     

Reaction of MeO2C(H)C=C=C(H)CO2Me with Ru3(CO)12. New diruthenium complexes with bridging carboxylate-substituted allene ligands

The reaction of Ru₃(CO)₁₂ with MeO₂C(H)C=C=C(H)CO₂ Me has yielded two isomeric productsanti-Ru₂(CO)₆[μ-η ³-η ¹-MeO₂C(H)CCC(H)CO₂Me],1 in 70% yield andsyn-Ru₂(CO)₆[μ-η ³-η ¹-MeO₂C(H)CCC(H)CO₂Me],2 in 5% yield. Both compounds were characterized by single crystal X-ray diffraction analysis. Both products are diruthenium complexes with bridging di(carboxylate)allene ligands in which the oxygen atom of the carbonyl group of one of the carboxylate groupings is coordinated to one of the metal atoms. Compound1 isomerizes partially to2 at 68°C. Crystal Data for1: space group=P2₁/n,a=11.131(1) Å,b=10.228(2) Å,c=15.978(2) Å,β=102.01(1)°,Z=4, 1653 reflections,R=0.025; for2: space group=P $\bar 1$ ,a=9.340(1) Å,b=14.925(4) Å,c=6.778(2) Å,α=99-02(2)°,β=104 62(2)°,γ=94.58(2)°,Z=2, 1857 reflections,R=0.027.     

Chemistry of Fischer-type rhenacyclobutadiene complexes. I. Deprotonation, addition/substitution of nucleophilic reagents at α-carbon, and insertion of heteroatoms into rhenium-carbon bonds

The rhenacyclobutadienes (CO)₄Re(η²- C(R)C(CO₂Me)C(OR^′)) (2) undergo a number of reactions that mirror those of Fischer alkoxycarbene complexes. Thus, (CO)₄Re(η²-C(Me)C(CO₂Me)C(OEt)) (2a) can be deprotonated by LDA, Na[OBu-t], or Na[CH(CO₂Me)₂] to give the ylide-like conjugate base [(CO)₄Re(η²-C(CH₂)C(CO₂Me)C(OEt)]⁻ (3), which was isolated as PPN(3). Li(3) undergoes deuteriation with DCl/D₂O and alkylation with Et₃OPF₆ at ReCCH₂, with the latter reaction affording (CO)₄Re(η²-C(CH₂Et)C(CO₂Me)C(OEt)) (4). Repetition of the sequence deprotonation-ethylation on 4 generates (CO)₄Re(η²-C(CHEt₂)C(CO₂Me)C(OEt)) (5). The nature of the alkoxy substituent in 2 can be varied by use of the rhenacyclobutenones Na[(CO)₄Re(η²-C(R)C(CO₂Me)C(O))] (Na(1)) in conjunction with AcCl and R^′OH to produce a series of new complexes (R=Ph, R^′=Et (2b); R=Me, R^′=CH₂CHCH₂ (2c), (CH₂)₃CCH (2d), Me (2e)). Aminolysis of 2a with the primary and secondary amines PhNH₂, HO(CH₂)₂NH, p-TolNH₂, and Et₂NH yields the aminorhenacyclobutadiene complexes (CO)₄Re(η²-C(Me)C(CO₂Me)C(NHR^′ or NR^′₂)) (R₂^′=Et₂ (6a); R^′=Ph (6b), (CH₂)₂OH (6c), p-Tol (6d)). These complexes display lesser carbene-like character than their alkoxy counterparts 2, as evidenced by ¹H and ¹³C NMR spectroscopic properties and lack of reactivity toward LDA by 6a. Reactions of each 2a and 6a with PPhMe₂ at low temperature afford (CO)₄Re(η²-C(Me)(PPhMe₂)C(CO₂Me)C(OEt)) (7) and (CO)₃(PPhMe₂)Re(η²-C(Me)C(CO₂Me)C(NEt₂)) (9), respectively, further in agreement with the more carbenoid nature of 2a than 6a. 7 undergoes conversion to (CO)₃(PPhMe₂)Re(η²-C(Me)C(CO₂Me)C(OEt)) (8) upon heating. 2a reacts with each of (NH₄)₂[Ce(NO₃)₆], DMSO, EtNO₂/Et₃N, and Me₃NO under various conditions to afford one or both of the oxygen atom insertion products into the ReC bonds, (CO)₄Re(κ²-OC(Me)C(CO₂Me)C(OEt)) (10) and (CO)₄Re(κ²-C(Me)C(CO₂Me)C(OEt)O) (11). In contrast, no reaction occurred between 2a and S₈ on heating. However, 6a was converted to the NH insertion product (CO)₄Re(κ²-NHC(Me)C(CO₂Me)C(NEt₂)) (12) by the action of H₂NNH₂ · H₂O at 0 °C. All new compounds were characterized by a combination of elemental analysis, mass spectrometry, and IR and NMR spectroscopy.