Reactions of delocalized dianions with transition metal complexes. Electron transfer in the reaction of the isobutylene dianion with molybdenum carbonyl dihalides

Reaction of the dianion of isobutylene with Mo- (CO)₃(PPh₃)₂X₂ results in the reduction of the metal and concomitant oxidation of the dianion. The reduction parallels the previously reported electrochemical reduction. Reaction of the dianion with Mo(CO)₄X₂ results in reduction of the metal presumably to coordinatively unsaturated Mo(CO)_x (x = 5, 4) which is then trapped by solvent or tertiary amines in solution to give Mo(CO)₄L₂ (L₂ = (THF)₂, TMEDA). The reduction potentials for Mo(CO)₃- (PPh₃)₂X₂ allow an estimate of the oxidation potential of the isobutylene dianion to be greater than −0.35 V versus SCE. Cp₂TiCl₂, which is not reduced by the isobutylene dianion, allows the estimate of the upper limit of the oxidation potential to be evaluated as less that −0.88 V versus SCE. The dianion is therefore by this criterion, less stable than the cyclopentadienyl anion (Ep = −0.18 V versus SCE) but more stable than the allyl anion (Ep = −1.40 V versus SCE).     

Fast atom bombardment,electron impact and chemical ionization mass spectrometry of the neutral 18-electron species M(CO)2(CNR)2(PR′3)2 (MMo or W)

The molybdenum(0) and tungsten(O) complexes of the type M(CO)₂(CNR)₂(PR′₃)₂ have been studied using a variety of mass spectral techniques, viz. fast atom bombardment (FAB), electron impact (EI), and both positive- and negative-ion chemical ionization (PICI and NICI) mass spectrometry. The FABMS technique gave the most structurally informative spectra with the observation of the molecular ions M⁺ (100% relative abundance in the case of MW) and in some instances the pseudomolecular ion (M + H)⁺. Fragmentation ions arising from competitive ligand loss (CO versus RNC versus PR′₃) were observed, as well as those formed by loss of H from fragment ions and dealkylation of RNC ligands. The EI and PICI spectra were not especially useful due to the relatively low thermal stability of these complexes, while the NICI spectra gave an abundance of ions that resulted from ligand redistribution reactions. Of special note were anions that contained M(CO)₄ and M(CO)₃ fragments. Dealkylation of the RNC ligands to give cyanometallate anions was also prevalent.     

Reaction of Mo(CO)4(NCCH3)2 and 7-aza-2-Tosylnorbornadiene

Reaction of Mo(CO)₄(NCCH₃)₂ and 7-aza-2-tosylnorbornadiene (7-azaNBD) yielded five air-stable Mo complexes. One is Mo(CO)₄(η⁴-7-azaNBD), in which the molybdenum atom is chelated by the two π-bonds of 7-azaNBD. The other four are isomers of Mo(CO)₂(η²-7-azaNBD)₂, in which the molybdenum atoms are chelated by the nitrogen atom and one of the two double bonds of 7-azaNBD. In one pair of the isomers, the metal binds to C(2)C(3) of both 7-azaNBD ligands; whereas in the other pair of isomers the metal binds to C(2)C(3) of one 7-azaNBD ligand and C(5)C(6) of another ligand. All structures were fully characterized by NMR spectra. A single crystal of compound 4 was analyzed by X-ray diffraction analysis, which was found to be monoclinic with a = 8.4199, b = 23.984, c = 16.395 Å, and β = 99.99°.     

Redox potentials of trinuclear μ-oxo ruthenium acetate clusters with N-heterocyclic ligands

The trinuclear clusters of general composition [Ru₃O(OOCCH₃)₆(N-Het)₃], where N-Het=pyridine and pyrazine derivatives, exhibit a series of reversible waves in the range of −1.8 to 2.4 V versus SHE, in acetonitrile, ascribed to the successive [cluster]^{−2/−1/0/+1/+2/+3} redox couples. The redox potentials decrease with the pK_a of the N-heterocyclic ligands according to the equations E°(+3/+2)= 2.24−0.023 pK_a; E°(+2/+1)=1.34−0.029 pK_a; E°(+1/0)=0.36−0.039 pK_a and E°(0/−1)=−0.68− 0.074 pK_a. The dependence is greater at lower oxidation states, reflecting the role of π-backbonding in the complexes.     

Synthesis,structure, reactivity and electrochemistry of a new molybdenum(0) dithiocarbamato complex, [Et4N][Mo(CO)4(S2CNEt2)]

A new molybdenum(0) dithiocarbamato complex [Et₄N] [Mo(CO)₄(S₂CNEt₂)] (1) has been synthesized by the reaction of Mo(CO)₆, NaS₂CNEt₂ and Et₄NCl in MeCN and characterized by routine elemental analysis, spectroscopy methods. The crystal and molecular structure of 1 was determined from X-ray three dimension data. 1 crystallizes in the orthorhombic, space group Pbc2₁ with a= 8.148(2), b=19.618(2), c=14.354(2) Å; V=2294 ų; Z=4; R₁=0.052, R₂=0.058 for 1308 independent reflections with I ⩾ 3σ(I). The geometry around Mo(0) atom in the anion [Mo(CO)₄(S₂CNEt₂)]^- of 1 is distorted octahedral with a small SMoS of 67.70° and a small angle of 3.6° between plane MoSS and MoC(1)C(2). Two groups of MoCO bond distances and the longer MoS bond distance observed in 1 are similar to that in the dinuclear Mo(0) complexes containing SR bridges but very different from those observed in the dithiocarbamato complexes of Mo in higher oxidation states. Different oxidizing products containing Mo in II-V oxidation states Mo(CO)₂(S₂CNEt₂)₂, MoO(S₂CNEt₂)₂, Mo₂O₃(S₂CNEt₂)₄ and Mo₂O₄(S₂CNEt₂)₂ were isolated from the oxidation of 1 with I₂ (or in the presence of traces of air). The electrochemical behavior of 1 in MeCN was investigated by cyclic voltammetry at Pt and C electrodes. The anodic peaks observed at 0.04, 0.14, 0.26 and 0.44 V versus SCE implied that 1 probably underwent oxidation in company with dissociation of dithiocarbamate and substitution of carbonyls resulting in several complexes of Mo in different oxidation states. The relationship between reactivity and structure is also discussed.     

Metal cluster topology. 4. Rhodium carbonyl clusters having fused polyhedra

Previously discussed topological models of metal cluster bonding are now extended to the treatment of anionic rhodium carbonyl clusters having structures consisting of fused polyhedra. Examples of such rhodium carbonyl clusters built from fused octahedra include the ‘biphenyl analogue’ [Rh₁₂(CO)₃₀]⁻², the ‘face-sharing naphthalene analogue’ [Rh₉- (CO)₁₉]³⁻, and the ‘perinaphthene analogue’, [Rh₁₁- (CO)₂₃]³⁻. More complicated anionic rhodium carbonyl clusters treated in this paper include the [Rh₁₃(CO)₂₄H_5−q]^q− anions (q = 2, 3, 4) having an Rh₁₃ centered cuboctahedron, the [Rh₁₄(CO)₂₅- H_4−q]^q− (q = 3,4) and [Rh₁₄(CO)₂₆]²⁻ anions based on a centered pentacapped cube, the [Rh₁₅- (CO)₃₀]³⁻ anion having an Rh₁₅ centered 14-vertex deltahedron, the [Rh₁₅(CO)₂₇]³⁻ anion having a tricapped centered 11-vertex polyhedron, the [Rh₁₇- (CO)₃₀]³⁻ anion having a tetracapped centered cuboctahedron, and the [Rh₂₂(CO)₃₇]⁴⁻ anion having a hexacapped centered cuboctahedron fused to an octahedron so that the octahedron and the cuboctahedron share a triangular face. Analyses of the bonding topologies in [Rh₉(CO)₁₉]³⁻, [Rh₁₇- (CO)₃₀]³⁻, and [Rh₂₂(CO)₃₇]⁴⁻ indicate that a polyhedral network containing several fused globally delocalized polyhedral chambers will not necessarily have a multicenter core bond in the center of each such polyhedral chamber. This observation is of potential importance in extending topological models of metal cluster bonding to bulk metals.     

Interaction of tin methylchlorides SnMenCl4−n with molybdenum hydride bis(cyclopentadienyl)

The interaction between Cp₂MoH₂ (Cp=η⁵- C₅H₅) and SnMe_nCl_4−n (n=0−3) proceeds in aprotic solvent with the elimination of HCl and the formation of heterometallic complexes of the composition Cp₂Mo(H)SnMe_nCl_3−n (n=0−3) and Cp₂Mo(SnMe₂Cl)₂ which contains an MoSn σ-bond. It has been found that in all studied compounds the length of this bond is 0.20–0.30 Å less than the sum of the covalent radii of the Mo and Sn atoms.Based on analysis of the geometry of the Mo and Sn environment, the high values of the isomeric shifts (IS) in the Mössbauer spectra, the constants of the spin-spin interactions (SSI) J³_Cp-Sn and J²_HMoSn, and the considerably decreased values of the J²_Me-sn constants in ¹H NMR spectra, it was concluded that the decrease in the interatomic distance Mo-Sn is due to the high s-character of this bond. It is suggested that this effect, which is most pronounced in wedge-like complexes, is brought about by changing the orbital hybridization type of the tin atom from sp³ to s + 3p. This can explain the shorter interatomic distance M-Sn in heterometallic complexes of other types.     

Effect of solvent environment on the CO band position in the infrared spectrum of trans-[Fe(CN)4(CO)2]

Density functional theory (DFT) is used to understand the effect of hydrogen bonding solvents on the CO band position in the infrared (IR) spectrum of a mono-iron complex, trans-[Fe^II(CN)₄(CO)₂]²⁻. This mono-iron complex has received much attention recently due its potential relation to the biosynthesis of Fe-only hydrogenase enzymes. Our calculations show that the polar solvent molecules preferentially hydrogen bond to the cyano ligands in this complex. The effect of such hydrogen bonding on the electron density distribution is analyzed in terms of the population in natural bond orbitals (NBO). Our results show that the presence of hydrogen bonding to the cyano ligands decreases the extent of back bonding from the metal to the carbonyl ligand. This results in decreased electron density in the π^∗ orbitals of the carbonyl bond leading to a strengthening of the CO bond and a consequent blue shift in the IR band position of the carbonyl group. We also show that the extent of blue shift correlates with the number of nearest neighbor solvent molecules.     

Carbonyl complexes of Rh(I), Ir(I) and Mo(0) containing substituted derivatives of 1,10-phenanthroline and 2,2′-bipyridine

The A₁ symmetry v_CO of the carbonyl complexes [Mo(chel)(CO)₄], [M(chel)(CO)₂] [PF₆] (M=Rh, Ir; chel=bipy, phen and substituted derivatives) are used for determining the electron donor-acceptor properties of the title ligands. The steric hindrance of the methyl groups in positions 2 and 9 of the phenanthroline favours the formation of Rh(I) and Ir(I) pentacoordinated derivatives.     

Structural and vibrational characteristics of the tetrasulfatodimolybdenum ions with MoMo bond orders of 3.5 and 4.0

The compound K₄[Mo₂(SO₄)₄]Br·4H₂O has been made and its crystal structure determined. Space group P4/mnc; unit cell dimensions, a = 11.903(2), c = 8.021(1) Å, V = 1136(1) ų. The compound is isomorphous with the analogous chloride whose structure has been reported. The MoMo and MoBr distances are 2.169(2) and 2.926(1) Å, respectively and the [Mo₂(SO₄)₄] ³⁻ ions reside on crystallographic special positions with 4/m symmetry. The Raman spectra of both the bromo and chloro compounds have been measured and the MoMo stretching frequency is 370 ± 1.5 cm⁻¹ in each, for the compounds containing the natural isotopic distribution of molybdenum. The chloro compound has been prepared containing the pure isotope ⁹²Mo as well, and the Raman spectra recorded. The v(MoMo) band is shifted by 6.8 ± 0.5 cm⁻¹. The compound K₄[Mo₂(SO₄)₄]·2H₂O has also been prepared with Mo at natural abundance and with the pure isotope ¹⁰⁰Mo, whereby a shift of 8.5 ± 0.5 cm⁻¹ was found. These and other results will be discussed with regard to the similarity of the Raman spectra of the Mo₂(S0₄)₄³⁻ and M0₂(S0₄)₄⁴⁻ species.     

Infrared spectra and structure of bridging carbonyls in Fe2Ru(CO)12 and Fe3(CO)12

IR spectra of crystal, solution and pseudo-gas phases (argon and nitrogen matrices) of Fe₂Ru(CO)₁₂ and of crystal and solution phases of Fe₃(CO)₁₂ were recorded. By quantitative data-handling procedures, structures and bond angles for bridging carbonyls were estimated. Fe₂Ru(CO)₁₂ in crystal has a bridging structure analogous to that of Fe₃(CO)₁₂, with two bridged carbonyls and C_2v or pseudo-C_2v symmetry. In solution, both samples contain the same carbonyl bridged structure of C_2v symmetry,just as in pseudo- gas phase; the latter, however, contains other bridged molecules of unknown structures, too.     

Electrochemical oxidation of Mo(CO)4(LL) and Mo(CO)3(LL)(CH3CN): Generation, infrared characterization, and reactivity of [Mo(CO)4(LL)] and [Mo(CO)3(LL)(CH3CN)] (LL = 2,2′-bipyridine, 1,10-phenanthroline and related ligands)

Mo(CO)₄(LL) complexes, where LL = polypyridyl ligands such as 2,2′-bipyridine and 1,10-phenanthroline, undergo quasi-reversible, one-electron oxidations in methylene chloride yielding the corresponding radical cations, [Mo(CO)₄(LL)]⁺. These electrogenerated species undergo rapid ligand substitution in the presence of acetonitrile, yielding [Mo(CO)₃(LL)(CH₃CN)]⁺; rate constants for these substitutions were measured using chronocoulometry and were found to be influenced by the steric and electronic properties of the polypyridyl ligands. [Mo(CO)₃(LL)(CH₃CN)]⁺ radical cations, which could also be generated by reversible oxidation of Mo(CO)₃(LL)(CH₃CN) in acetonitrile, can be irreversibly oxidized yielding [Mo(CO)₃(LL)(CH₃CN)₂]²⁺ after coordination by an additional acetonitrile. Infrared spectroelectrochemical experiments indicate the radical cations undergo ligand-induced net disproportionations that follow first-order kinetics in acetonitrile, ultimately yielding the corresponding Mo(CO)₄(LL) and [Mo(CO)₂(LL)(CH₃CN)₃]²⁺ species. Rate constants for the net disproportionation of [Mo(CO)₃(LL)(CH₃CN)]⁺ and the carbonyl substitution reaction of [Mo(CO)₃(LL)(CH₃CN)₂]²⁺ were measured. Thin-layer bulk oxidation studies also provided infrared characterization data of [Mo(CO)₄(ncp)]⁺ (ncp = neocuproine), [Mo(CO)₃(LL)(CH₃CN)]⁺, [Mo(CO)₃(LL)(CH₃CN)₂]²⁺ and [Mo(CO)₂(LL)(CH₃CN)₃]²⁺ complexes.     

Ortho-metalation, rotational isomerization, and hydride-hydride coupling at rhenium (V) polyhydride complexes stabilized by aromatic amine ligands

An ortho-metalated rhenium (V) polyhydride complex has been prepared through the reaction of ReH₇(PPh₃)₂ with 2-phenylpyridine. Additionally, a small series of neutral rhenium (V) pentahydride complexes, each of which is stabilized by an aromatic amine ligand, has been prepared. E and Z rotational isomers of the ReH₅(PPh₃)₂(aromatic amine) complexes have been observed at low temperatures by NMR spectroscopy. The E and Z rotational isomers arise from a combination of the lack of a mirror plane symmetry element orthogonal to the aromatic ring in the aromatic amine ligands and the restricted rotation about the Re-N bond in such complexes. Restricted rotation about the Re-N bond in the related complex, ReH₅(PPh₃)₂(Py) has previously been observed by Crabtree et al. The restricted rotation about the Re-N bond seems to result from π-donation of the lone electron pair on the rhenium (V) center to the π∗ system of the aromatic amine ligands. Different populations of the E and Z rotational isomers arise from interactions of substituents on the aromatic ring with the other ligands bound to rhenium. The values of ΔG^‡ for the restricted rotation about the Re-N bonds, for the complexes containing 4-phenylpyrimidine, 2-aminopyrimidine, or 2-aminopyridine, range from 9.9 to 11.3 kcal/mole. One of the new compounds reported herein, ReH₅(PPh₃)₂[1-(2-NH₂Pyr)] is the first rhenium (V) polyhydride complex to display hydride-hydride coupling in its ¹H NMR spectrum.     

Oxidative addition of thiols to (CO)3Mo(μ-dppm)2Ru(CO)3 with formation of hydrido, bridged-thiolate complexes (dppm = Ph2PCH2PPh2)

The room temperature reactions of RSH (R = Et, Ph) with (CO)₃Mo(μ-dppm)₂Ru(CO)₃ (1) in toluene yield (CO)₂Mo(μ-SR)(μ-CO)(μ-dppm)₂Ru(H)(CO) [R = Et (3); Ph (4)], which are characterized by elemental analysis, ¹H NMR and IR spectroscopies and, in the case of 3, by X-ray crystallography. The complexes contain a trans,trans-Mo(μ-dppm)₂Ru unit with a bridging thiolate, a terminal hydride at the Ru, three terminal CO ligands (two at the Mo, and one at the Ru), and one semi-bridged CO closer to the Mo.     

On the electron delocalization in cyclopropenylidenes - An experimental charge-density approach

The extent and nature of cyclic electron delocalization in free and coordinated cyclopropenylidene carbenes has been analyzed by combined experimental and theoretical charge-density studies. The significant asymmetry of the C-C bond lengths in substituted cyclopropenylidene carbenes was identified as cooperative effect which depends on contributions of both σ- and π-bonding. We show that analyses of (i) the topology of the Laplacian of the electron density distribution and (ii) the out-of-plane atomic quadrupole moments - the charge-density analogues of p_π occupation - allow to distinguish between the influence of σ- and π-electrons on cyclic electron delocalization. These studies hint for pronounced electron localization in the carbene lone pair region which dominates the electronic structure of free cyclopropenylidene carbenes and hinders the establishment of true aromaticity. We further investigated the electron donating/withdrawing ability of cyclopropenylidene ligands relative to N-heterocyclic carbenes. The experimental benchmark systems LCr(CO)₅ (L = 2,3-diphenylcyclopropenylidene and 1,2-dimethylimidazol-2-ylidene) show that the cyclopropenylidene ligand clearly displays the higher π-acceptor capability relative to N-heterocyclic carbenes.     

A study of the thermal and photochemical reactions of the group 6 metal carbonyls with organic polymer supports

The synthesis of organic polymers containing metal carbonyl moieties is described. The reaction of [Mo(CO)₄(bipy)] with poly-4-vinylpyridine proceeds smoothly to give [Mo(CO)₃(bipy)(poly-4-vinylpyridine)] which has a fac configuration. The thermal chemistry of a variety of polymer-bound metal carbonyl compounds is also presented, as is evidence for the formation of [W(CO)₄(poly-4-vinylpyridinestyrene)] from [W(CO)₅(poly-4-vinylpyridinestyrene)]. Included is evidence for the decarbonylation of polymer-bound metal compounds resulting in polymers which contain fully decarbonylated metal centres. Preliminary photochemical investigations indicate the generation of active coordinatively unsaturated metal carbonyl species in polymer matrices at low temperatures.     

The synthesis and molecular structure of diiodooctacarbonyldiosmium(I), [Os2(CO)8I2]

The compound, diiodooctacarbonyldiosmium(I), [Os₂(CO)₈I₂], has been prepared by a route involving only atmospheric pressures. Its structure has been determined by X-ray crystallography. The crystals are tetragonal with a = 11.791(2), c = 23.583(4) Å, Z = 8, D_c = 3.48 Mg m⁻³. A total of 1637 reflections were collected out to θ = 25° on a CAD4 diffractometer in ω—2θ mode using Mo Kα (λ = 0.7107 Å) radiation. Lp and empirical absorption corrections were applied. The structure was solved in the space group I4₁cd using conventional heavy atom methods and refined to R = 0.0477 [R_w = 0.0424, w = (σ²F)⁻¹]. The molecule of [Os₂(CO)₈l₂] has two crystallographically equivalent halves joined by a single OsOs bond of length 2.947(3) )Å. There are no bridging ligands. The geometry about each osmium is pseudo-octahedral and the iodine atoms occupy equatorial positions with an OsI distance of 2.767(3) Å. The equatorial ligands on one osmium atom are staggered with respect to the equatorial ligands on the other osmium atom.     

Synthesis and structures of aryl-substituted tetramethylcyclopentadienyl dinuclear metal carbonyl complexes

A series of 14 aryl-substituted tetramethylcyclopentadienyl dinuclear metal carbonyl complexes have been synthesized by treating the corresponding ligands (C₅Me₄C₆H₄X-4) (X = H, Me, Cl, OMe) with Ru₃(CO)₁₂, Fe(CO)₅, or Mo(CO)₃(MeCN)₃, respectively in refluxing xylene. It showed that the electronic effects of the substituents had influence on the molecular structures and reactions of the complexes, especially for the ruthenium and molybdenum complexes. In the reactions of aryl-substituted tetramethylcyclopentadiene with Mo(CO)₃(MeCN)₃, the electron-withdrawing effect of the substituent in the para position of benzene ring is favorable to produce the Mo-Mo triple bonded complexes, but the electron-donor effect of the substituent in the para position of benzene ring is favorable to produce the Mo-Mo single bonded complexes. In a given condition, the Mo-Mo single bonded complex could be transformed into the corresponding Mo-Mo triple bonded complex. The structures of nine complexes were determined by single crystal X-ray diffraction.     

Reactions of ‘GaI’ with organometallic transition metal halides

Two approaches towards the synthesis of phosphine ligated half-sandwich complexes [(η^x-C_xH_x)M(PR₃)₂GaI₂]_n containing diiodogallyl ligands have been investigated. Insertion of ‘GaI’ into the Mo-I bond of (η⁷-C₇H₇)Mo(CO)₂I has been shown to yield the crystallographically characterized dimeric complex [(η⁷-C₇H₇)Mo(CO)₂GaI₂]₂ (2). Attempts to substitute the carbonyl ligands by the phosphine ligand dppe [dppe = bis(diphenylphosphino)ethane] have been shown instead to yield the sparingly soluble complex [(η⁷-C₇H₇)Mo(CO)₂GaI₂]₂(μ-dppe) (3) in which the phosphine bridges two [(η⁷-C₇H₇)Mo(CO)₂GaI₂] units via a pair of P → Ga donor/acceptor bonds. By contrast, attempts to insert ‘GaI’ directly into the metal-halogen bond of phosphine ligated complexes such as (η⁵-C₅H₅)Ru(PPh₃)₂Cl or (η⁵-C₅H₅)Ru(dppe)Cl have been shown to result in the formation of the tetraiodogallate species(η⁵-C₅H₅)Ru(PPh₃)₂(μ-I)GaI₃ (5) and [(η⁵-C₅H₅)Ru(dppe)]⁺[GaI₄]⁻ (7).     

Tetrazole and triazole carbene complexes of group 6 metal carbonyls

In order to study the relative stability of cis- and trans-isomers of bis(NHC)tetracarbonyl complexes of group 6 metals, we synthesized the corresponding complexes with triazolin- and tetrazolinylidene ligands. By reaction of the free carbene (L = 1,3,4-triphenyl-4,5-dihydro-1H-1,2,4-triazolin-5-ylidene) - first synthesized by Enders - with the hexacarbonyls of Cr, Mo and W the corresponding M(L)(CO)₅ complexes are generated. Depending on an excess of carbene also the cis-(L)₂Mo(CO)₄ complex was obtained. The latter can be photolytically converted to the trans-(L)₂Mo(CO)₄ complex. The corresponding complexes with the 1,4-dimethyltetrazolin-5-ylidene ligand (L′), Cr(L′)(CO)₅, cis-(L′)₂Cr(CO)₄ and trans-(L′)₂Cr(CO)₄ can be obtained by reaction of hexacarbonyl-μ-trihydroxy-dichromate with dimethyltetrazolium salt. In the cis-(L′)₂Cr(CO)₄ complex, one carbonyl ligand can be replaced by donor ligands such as pyridine or phenylisocyanide to form sym-mer-tricarbonyl complexes. All new complexes are fully characterized by spectroscopy and most by single-crystal X-ray analysis.