Oxidation reactions catalysed by molybdenum(VI) complexes grafted on UiO‐66 metal–organic framework as an elegant nanoreactor

A heterogeneous catalyst was synthesized by immobilizing Mo(CO)₃ in a UiO‐66 metal–organic framework. The benzene ring of the organic linker in UiO‐66 was modified via liquid‐phase deposition of molybdenum hexacarbonyl, Mo(CO)₆, as starting precursor to form the (arene)Mo(CO)₃ species inside the framework. The structure of this catalyst was characterized using X‐ray diffraction, and chemical integrity was confirmed using Fourier transform infrared and diffuse reflectance UV–visible spectroscopic methods. The metal content was analysed with inductively coupled plasma. Field emission scanning electron microscopy was used to measure particle size and N₂ adsorption measurements to characterize the specific surface area. This catalytic system was efficiently applied for epoxidation of alkenes and oxidation of sulfides. The Mo‐containing metal–organic framework was reused several times without any appreciable loss of its efficiency.     

Fast microwave promoted palladium-catalyzed synthesis of phthalides from bromobenzyl alcohols utilizing DMF and Mo(CO)6 as carbon monoxide sources

A fast method utilizing in situ generated CO for the synthesis of phthalides has been developed. DMF and Mo(CO)₆ were applied as two alternative CO-sources in these microwave promoted carbonylation-lactone formation reactions. Mo(CO)₆ was found to be the more generally applicable CO-source and provided phthalides as well as dihydroisocoumarin, dihydroisoindone, and phthalimide from the corresponding aryl bromide via an efficient CO insertion within a 1 h reaction time.     

Synthesis and spectroscopic studies of some new metal carbonyl derivatives of 1-(2-pyridylazo)-2-naphthol

Interaction of 1-(2-pyridylazo)-2-naphthol (PAN) with [Mo(CO)₆] in air resulted in formation of the tricarbonyl oxo-complex [Mo(O)(CO)₃(PAN)], 1. The dicarbonyl complex [Ru(CO)₂(PAN)], 3, was obtained from the reaction of [Ru₃(CO)₁₂] with PAN. In presence of triphenyl phosphine (PPh₃), the reaction of PAN with either Mo(CO)₆ or Ru₃(CO)₁₂ gave [Mo(CO)₃(PAN)(PPh₃)], 2, and [Ru(CO)₂(PAN)(PPh₃)], 4. All the complexes were characterized by elemental analysis, mass spectrometry, IR, and NMR spectroscopy. The thermal properties of the complexes were also investigated by thermogravimetry.     

Easy selective generation of (lithiomethyl)cyclopropane or homoallyllithium by a chlorine-lithium exchange

The reaction of (chloromethyl)cyclopropane 5 with lithium and a catalytic amount of DTBB (5 mol %) in the presence of different carbonyl compounds [Et₂CO, n-Pr₂CO, (c-C₃H₅)₂CO, (CH₂)₅CO, PhCOMe, t-BuCHO, i-PrCHO, PhCHO] as electrophiles in THF at −78 °C leads, after hydrolysis with water, to the corresponding cyclopropyl alcohols 6. However, when the same starting material is lithiated using naphthalene as the arene catalyst in ether at 0 °C and then reacts with the same series of electrophiles, the final hydrolysis with water yields the corresponding unsaturated alcohols 7.     

Umsetzungen von Allyldichlorphosphit und Allyldifluorphosphit mit einigen Verbindungen von Übergangsmetallen; Darstellung und spektroskopische Untersuchung von Allyldichlor- bzw. Allyldifluorphosphit-Carbonyl-Metall(0)-Koordinationsverbindungen (MetallCr,Mo, W,Fe)

Reactions of Allyldichlorophosphite and Allyldifluorophosphite with some Transition Metal Compounds; Synthesis and Spectroscopic Identification of Allyldichloro- and Allyldifluorophosphite-Carbonyl-Metal(0) Coordination Compounds (Metal?Cr, Mo, W, Fe) In the reactions of allyldifluorophosphite ( 1 ) and allyldichlorophosphite ( 2 ) with the carbonyl compounds (C₇H₈)M(CO)₃ (M?Cr, Mo; C₇H₈ ? cycloheptatriene), W(CO)₅THF (THF = tetrahydrofuran), Fe(CO)₅ or Fe₂(CO)₉ the allyldichloro- and allyldifluorophosphite-carbonyl-metal compounds fac-(AllOPF₂)₃Cr(CO)₃ 3 a , mer-(AllOPF₂)₃Cr(CO)₃ 3 b , fac-(AllOPF₂)₃Mo(CO)₃ 4 , fac-(AllOPCl₂)₃Mo(CO)₃ 5 , (AllOPF₂)W(CO)₅ 6 , (AllOPCl₂)W(CO)₅ 7 , (AllOPF₂)Fe(CO)₄ 8 and (AllOPCl₂)Fe(CO)₄ 9 were formed (All = CH₂?CHCH₂). In 8 and 9 the ligands 1 or 2 are axially orientated. The validity of the concept of hard and soft acids and bases (HSAB-concept) and of the 18-valency electron rule (18-VE-rule) was confirmed. The allyl dihalophosphites 1 and 2 coordinate via phosphorus. The allylic π-system was not involved in the coordinative bond. The characterization of the coordination compounds 3 , 4 , 5 a , 5 b und 6 ? 9 was based on their IR and NMR spectra, and on the mass spectra.     

Palladium-catalyzed carbonylative synthesis of N-(2-cyanoaryl)benzamides and sequential synthesis of quinazolinones

A convenient procedure for the synthesis of N-(2-cyanoaryl)benzamides has been developed. Using aryl bromides and 2-aminobenzonitriles as the substrates, Mo(CO)₆ as the CO source, the desired amides were produced in good yields. Quinazolinones were produced in good yields in a sequential manner as well.     

Kinetics and Mechanism of Co Substitution by Phosphites of Co4(CO)12

Abstract

The otherwise very fast CO substitution of Co₄(CO)₁₂ by P(OMe)₃ and P(OEt)₃ in aprotic solvents, affording phosphite-monosubstituted products was retarded by the use of CHCI₃ as solvent. This made it possible to investigate these reactions by conventional methods. Kinetic data were obtained by following changes in IR spectra during reaction. The rates show predominantly a ligand-dependent pathway, with the usual two-term rate law, rate = (k₁ + k₂ [P(OR)₃])C₄(CO)₁₂. It is suggested that the rates are retarded in protonic solvents by decreasing the nucleophilicity of phosphites due to a hydrogen bonding interaction between the H atom of CHCI₃ and the O atoms of the ligands.     

Clusteraufbau durch Photolyse von R3PAuN3. VIII. Synthese und Kristallstruktur von [(Ph3PAu)5Mo(CO)4]PF6 · CH2Cl2 und (Ph3PAu)3Co(CO)3

Cluster Synthesis by Photolysis of R₃PAuN₃. VIII. Synthesis and Crystal Structure of [(Ph₃PAu)₅Mo(CO)₄]PF₆ · CH₂Cl₂ and (Ph₃PAu)₃Co(CO)₃ Photolysis of a mixture of Ph₂PAuN₃ and Mo(CO)₆ in THF yields [(Ph₃PAu)₅Mo(CO)₄]⁺ (1), which can be crystallized from CH₂Cl₂/diisopropylether as orange 1 · PF₆ · CH₂Cl₂ with the space group P2₁/c and a = 1681.4(5), b = 2215.6(12), c = 2761.5(9) pm, β = 91.54(3)°, Z = 4. The Au₅Mo center of cluster 1 forms a capped trigonal bipyramid with the Mo atom in equatorial position and almost equal Mo? Au distances between 279.9(5) and 284.6(7) pm to all five Au atoms. The Au? Au distances range from 272.2(4) to 301.3(4) pm. The Mo(CO)₄ group causes three v(C0) at 1975, 1915 and 1890cm^?1. Reaction of Ph₃PAuCo(CO)₄ with Ph₃PAuPF₆ affords the known cluster cation [(Ph₃PAu)₄Co(CO)₃]⁺ in high yield. It can be degraded with C1^? to the neutral cluster (Ph₃PAu)₃Co(CO)₃ (2). 2 forms air stable, yellow crystals with the space group P2₁/n and a = 1359.4(4), b = 2041.0(5), c = 1853.2(6)pm, β = 91.47(1)°, Z = 4. The Au₃Co core of 2 has a tetrahedral structure with distances Co? Au between 250.4(1) and 254.0(2) pm and Au? Au between 279.5(1) and 285.1(1) pm. v(C0) are observed at 1963, 1905 and 1891 cm^?1. Reaction of 2 with [(Ph₃PAu)₄Co(CO)₃]⁺ yields the condensed cluster [(Ph₃PAu)₆AuCo₂(CO)₆]⁺.     

Organotransition-Metal Complexes of Multidentate Ligands 3. The Unexpected Derivatives of Bis(3,5-Dimethylpyrazol-1-YL)Methanetetracarbonylmolybdenlim(0) and-Tungsten(0) Complexes

Thermolysis of (H₂CPz′₂)M(CO)₄ (H₂CPz′₂ = bis(3,5-dimethylpyrazol-1-yl)methane; M=Mo, W) in 1,2-dimethoxyethane did not give the expected 16-electron complexes, (H₂CPz′₂)M(CO)₃, but gave dinuclear compounds, [(H₂CPz′₂)M(CO)₃]₂, probably containing two linear carbonyl bridges and no metal-metal interactions. The dimers reacted with CH₃CN to give mononuclear compounds, (H₂CPz′₂)M(CO)₃(NCCH₃), identical to the substitution products between (H₂CPz′₂)M(CO)₄ and CH₃CN.     

Two molybdenum pentacarbonyl complexes with electroneutral phosphane ligands: [bis(morpholin‐4‐yl)(pentafluoroethyl)phosphane‐κP]pentacarbonylmolybdenum(0) and pentacarbonyl[(pentafluoroethyl)bis(piperidin‐1‐yl)phosphane‐κP]molybdenum(0)

The crystal structures of the title compounds, [Mo{(C₄H₈NO)₂P(C₂F₅)}(CO)₅], (1a), and [Mo{(C₅H₁₀N)₂P(C₂F₅)}(CO)₅], (2a), were determined as part of a larger project that focuses on the synthesis and coordination chemistry of phosphane ligands possessing moderate (electroneutral, i.e. neither electron‐rich nor electron‐deficient) electronic characteristics. Both complexes feature a slightly distorted octahedral geometry at the metal center, due to the electronic and steric repulsions between two of the four equatorial CO groups and the pentafluoroethyl group attached to the phosphane ligand. Bond length and angle data for (1a) and (2a) support the conclusion that the free phosphane ligands are electroneutral. For complex (1a), the Mo—P, Mo—C_ax and Mo—C_eq(ave) bond lengths are 2.5063 (5), 2.018 (2) and 2.048 (2) Å, respectively, and for complex (2a) these values are 2.5274 (5), 2.009 (3) and 2.050 (3) Å, respectively. Geometric data for (1a) and (2a) are compared with similar data reported for analogous Mo(CO)₅ complexes.     

Syntheses and Characterization of Molybdenum Complexes with the (1,3-Dithioliumyl)diphenylphosphine Containing Ligands

Treatment of [Et₄N][Mo(CO)₅(PPh₂CS₂)], 1 with unsaturated organic halides afforded the neutral complexes Mo(CO)₅(PPh₂CS₂R) (R = CH₂CN, 2 ; R = CH₂C≡CH, 3 ). Alkylation reactions take place at the sulfur atom. Protonation of complex 2 and 3 with HBF₄ produced the intramolecular cyclization products [Mo(CO)₅(PPh₂CS₂C₂H₃N)][BF₄], 4 and [Mo(CO)₅(PPh₂CS₂C₃H₄)][BF₄], 5 , respectively. In complex 4 and 5 , two five-membered 1,3-dithiolium rings formed. Protonation of 3 to 5 is not reversible, but deprotonation of 4 by n-BuLi or PPh₃ gave 2 quantitatively. Treatment of 4 with n-Bu₄NF yielded complex Mo(CO)₅PPh₂F, 6 and 2 with 1:1 ratio, but in the reaction of 5 and n-Bu₄NF only compound 6 was formed. All of these complexes are identified by spectroscopic methods.     

Mono- und Di-t-butylcyclopentadienyl-Carbonyl-Komplexe des Eisens und Molybdäns. Die Kristallstruktur von [Cp″Mo(Co)2]2 (Cp″ = n5-C5H3t-Bu2-1,3)

Mono- and Di-t-Butylcyclopentadienyl Carbonyl Complexes of Iron and Molybdenum — Crystal Structure of [Cp″Mo(CO)₂]₂ (Cp″ = n⁵-C₅H₃-t-Bu₂-1,3) Cothermolysis of M(CO)_m (M = Fe, m = 5; M = Mo, m = 6) with t-Bu-substituted cyclopentadienyls constitutes a simple synthesis of complexes of the type [Cp*M(CO)_n]₂ (CP* = n⁵-C₅H₃ (t-Bu), R, R = H, t-Bu; M = Fe, Mo; n = 2, 3). Each synthesis has an optimal temperature. The yield of Fe complexes decreases at temperatures above 130°C because of decomposition of the product. Optimal yields of [Cp*Mo(CO)₃]₂ are obtained at 130–140°C, whereas at 160°C complexes of the type [Cp*Mo(CO)₂]₂ with formal Mo? Mo triple bonds are obtained. The structure of the complexes is discussed on the basis of ¹H-, ¹³C-NMR, IR, and mass spectrometry. The structure of [Cp″Mo(CO)₂]₂ (Cp″ = n⁵-C₅H₃t-Bu₂-1,3) was determined by X-ray crystallography at ?95°C. It crystallises in the space group Pbca, with cell constants a = 1808.6(6), b = 1308.5(4), c = 2507.9(9) pm, Z = 8, R = 0.031 for 3794 reflections. The Mo? Mo bond length of 253.3 pm is very long for a formal triple bond. The Cp″? Mo? Mo? Cp″ axis is non-linear.     

Haptotropic migration of M(CO)3 (M = Cr, Mo, W) on substituted phenanthrene

The haptotropic migration of Cr(CO)₃, Mo(CO)₃ and W(CO)₃ moieties on a substituted phenanthrene has been studied theoretically using gradient-corrected density functional theory. The stationary points (minima and transition states) on the energy hypersurface characterizing the migrating process of the metal fragment over the aromatic system have been located. Furthermore, the energetic and structural differences between complexes of the three metals Cr, Mo and W and the effect of a high substitution of one arene ring on the reaction energy profile have been analyzed. The possibility to design a molecular switch based on the substituent pair R = O⁻/OH is investigated. It is concluded that the Mo and W complexes undergo a haptotropic migration more easily than the corresponding Cr system.     

Reactions of GeMe2-bridged dicyclopentadienes with molybdenum carbonyl: formation of germylidyne trimolybdenum clusters

In thermal reactions of the doubly bridged dicyclopentadienes (C₅H₃R(SiMe₂))(C₅H₃R(GeMe₂)) (R=H (1), ^tBu (5)) with Mo(CO)₆, the bridging GeMe₂ is cleaved to give the corresponding degermylated products [(η⁵-C₅H₃R)₂(SiMe₂)]Mo₂(CO)₆ (3, rac-7), or both GeMe₂ and SiMe₂ are cleaved to afford the nonbridged products [(η⁵-C₅H₄R)Mo(CO)₃]₂ (2, 6). The reactions also produce germylidyne trimolybdenum clusters [(η⁵-C₅H₃R)₂(SiMe₂)](η⁵-C₅H₄R)[Mo(CO)₂]₃(μ₃-GeMe) (4, rac-/meso-7) containing the Mo₃(μ₃-GeMe) units. Similarly, reaction of the single GeMe₂-bridged dicyclopentadienes (C₅H₅)₂GeMe₂ (9) with Mo(CO)₆ also results in the degermylated 2, as well as the similar trimolybdenum cluster [(η⁵-C₅H₅)Mo(CO)₂]₃(μ₃-GeMe) (10). The molecular structures of 4 and trans-5 were determined by X-ray diffraction.     

A facile and efficient deoxygenation of amine-N-oxides with Mo(CO)6

A variety of amine-N-oxides have been found to be selectively deoxygenated to the corresponding amines in high yields with Mo(CO)₆ in ethanol under mild conditions.     

Syntheses and characterization of two oxoborates, (Pb3O)2(BO3)2MO4 (M=Cr, Mo)

Two oxoborates, (Pb₃O)₂(BO₃)₂MO₄ (M=Cr, Mo), have been prepared by solid-state reactions below 700 °C. Single-crystal XRD analyses showed that the Cr compound crystallizes in the orthorhombic group Pnma with a=6.4160(13) Å, b=11.635(2) Å, c=18.164(4) Å, Z=4 and the Mo analog in the group Cmcm with a=18.446(4) Å, b=6.3557(13) Å, c=11.657(2) Å, Z=4. Both compounds are characterized by one-dimensional chains formed by corner-sharing OPb₄ tetrahedra. BO₃ and CrO₄ (MoO₄) groups are located around the chains to hold them together via Pb–O bonds. The IR spectra further confirmed the presence of BO₃ groups in both structures and UV–vis diffuse reflectance spectra showed band gaps of about 1.8 and 2.9 eV for the Cr and Mo compounds, respectively. Band structure calculations indicated that (Pb₃O)₂(BO₃)₂MoO₄ is a direct semiconductor with the calculated energy gap of about 2.4 eV.     

Chromium Tricarbonyl η6-Complexes of (η5-Cyclopentadienyl)(η4-1,3-Diphenylcyclobutadiene)Cobalt

The reaction of (η⁵-cyclopentadienyl)(η⁴-1,3-diphenylcyclobutadiene)cobalt ( I ) with excess Cr(CO)₃py₃ in BF₃OEt₂ yielded two identified heterometallic compounds. Compounds II and III with one and two phenyl rings complcxed with Cr(CO)₃ fragment(s), respectively. These compounds were characterized by mass, infrared, ¹H and ¹³C NMR spectra and elemental analysis. The crystal structure of II was determined. The Cr(CO)₃ fragment bends inward toward the cyclobutadicne ring due to its electron-withdrawing ability, in accord with Hunter's postulate. A sharp line due to the non-complexed phenyl ring was observed in the ¹HNMR spectrum, which implies that five protons are magnetically equivalent. The chemical shifts of two protons of the cyclobutadiene ring decreased from I to II then to III , possibly because of diminished deshielding effect from the phenyl ring in (arene)Cr(CO)₃.     

Highlights of the spectroscopy, photochemistry and electrochemistry of [M(CO)4(α-diimine)] complexes, M=Cr, Mo, W

Tetracarbonyl-diimine complexes [M(CO)₄(α-diimine)] (M=Cr, Mo, W; α-diimine=polypyridyl (bpy, phen), pyridine-2-carbaldehyde (R-PyCa) or 1,4-diaza-butadiene, (R-DAB)) have very interesting structural, spectroscopic, electrochemical and photochemical properties. Their comprehensive experimental and theoretical investigations have important implications for our understanding of the chemistry of organometallic complexes with noninnocent ligands. The most interesting physical and chemical aspects of [M(CO)₄(α-diimine)] complexes, which have more general relevance, are highlighted and discussed.     

Structure and Reactivity of Iron(0)-Phenyltellurolate [PPN][PhTeFe(CO)4]

Anionic iron(0) tetracarbonyl with terminal phenyltellurolate ligand PhTe^?, [PhTeFe(CO)₄]^?, has been synthesized and characterized. The title compound was obtained by addition of (PhTe)₂ to [PPN][HFe(CO)₄] THF solution dropwise. [PPN][PhTeFe(CO)₄] crystallizes in the monoclinic space group C c, with a = 16.119(4) Å, b = 13.141(3) Å, c = 19.880(8) Å, β = 93.04(3)°, V = 4205(2) ų, and Z = 4. The [PhTeFe(CO)₄]^? anion is a trigonal-bipyramidal complex in which the phenyltellurolate ligand occupies an axial position with Fe-Te bond length 2.630(5) Å and the Fe-Te-C(Ph) angle is 103.4(5)°. The neutral iron(0)-telluroether compound, (PhTeMe)Fe(CO)₄, was prepared by alkylation of the [PhTeFe(CO)₄]^?. Protonation of [PhTeFe(CO)₄]^?and reaction of H₂Fe(CO)₄ and PhTe)₂ ultimately lead to formation of the known dimer Fe₂(μ-TePh)₂(CO)₆ and H₂.     

Thermochemistry of molybdenum tricarbonyl complexes of arenes and cyclic polyolefins

The heats of reaction of arene, cycloheptatriene, and cyclooctatetraene complexes of molybdenum tricarbonyl with pyridine yielding (py)₃Mo(CO)₃ have been measured by solution calorimetry. Reaction of toluene molybdenum tricarbonyl with cyclopentadiene yielding HMo(CO)₃C₅H₅ and with tetrahydrofuran yielding (THF)₃Mo(CO)₃ have also been studied thermochemically. These measurements yield accurate values for the enthalpy of arene exchange in methylene chloride solution for a number of organomolybdenum complexes. The order of stability: benzene < toluene < cyclooctatetraene < mesitylene < hexamethylbenzene < cycloheptatriene < (tris)-tetrahydrofuran < η⁵-cyclopentadienylhydrido < (tris)-pyridine spans a range of 31 kcal/mol.The enthalpy of isomerization of cycloheptatriene to toluene is reduced by 7.1 ± 1.2 kcal/mol upon coordination to molybdenum tricarbonyl, indicative of a loss of “resonance” energy for the complexed arene. The MoH bond strength in HMo(CO)₃C₅H₅ is estimated as 66 ± 8 kcal/mol. The importance of entropic factors in arene exchange is discussed.