The oxidative addition of methyl iodide to β-diketonecarbonyltriphenylphosphinerhodium(I) complexes

The kinetics and mechanism of the reaction [Rh(β-diketone)(CO)(PPh₃)] + CH₃I → [Rh(β-diketone)(CH₃)(I)(CO)(PPh₃)] where β-diketone = acac, TFDMAA, TFAA and HFAA, were studied with the aid of i.r. and visible spectrophotometry. The reaction proceeds by two consecutive steps through a postulated ionic intermediate. The influence of phosphine dissociation, solvent polarity, alkyl group variation and different electronegative β-diketone substituents on the reaction rate were investigated. The rate constant for a methyl-acyl → metal-alkyl conversion (CH₃ migration) was determined.     

Oxidative addition of methyl iodide to [Rh(CH3COCHCOCH3)(CO)(P(OCH2)3CCH3)]

The reaction rate of the oxidative addition and the following CO insertion step of methyl iodide with [Rh(acac)(CO)(P(OCH₂)₃CCH₃)] is determined. The key finding is that while [Rh(acac)(CO)(P(OCH₂)₃CCH₃)] oxidatively adds methyl iodide ca 300 times faster than the Monsanto catalyst, the CO insertion step is much slower. However, the rate-determining step of the oxidative addition reaction of the phosphorus-containing acetylacetonato-rhodium(I) complex, the carbonyl insertion step, is still in the same order or faster than the rate-determining oxidative addition step of iodomethane to [Rh(CO)₂I₂]⁻.     

Synthesis and NMR characterization of cationic rhodium(I) complexes containing phosphorus—sulfur bidentate ligands

The reaction of [Rh(diene)(acac)] (diene=cyclooctadiene or norbornadiene; acac=acetylacetonate) with bidentate ligands of the type Ph₂P(CH₂)_nSR (n=1, 2 or 3; R=Me, Et, Ph, not all combinations) or cis-Ph₂PCHCHPPh₂ leads to [Rh(diene)(LL)]⁺ or [Rh(LL)₂]⁺, depending on the stoichiometry of the reaction. The complexes were fully characterized by ¹H and ³¹P NMR spectroscopy.     

Oxidative addition of methyl iodide to [Rh(CO)2I]2: synthesis, structure and reactivity of neutral rhodium acetyl complexes, [Rh(CO)(NCR)(COMe)I2]2

Reaction of [Rh(CO)₂I]₂ (1) with MeI in nitrile solvents gives the neutral acetyl complexes, [Rh(CO)(NCR)(COMe)I₂]₂ (R=Me, 3a; ^tBu, 3b; vinyl, 3c; allyl, 3d). Dimeric, iodide-bridged structures have been confirmed by X-ray crystallography for 3a and 3b. The complexes are centrosymmetric with approximate octahedral geometry about each Rh centre. The iodide bridges are asymmetric, with Rh-(μ-I) trans to acetyl longer than Rh-(μ-I) trans to terminal iodide. In coordinating solvents, 3a forms mononuclear complexes, [Rh(CO)(sol)₂(COMe)I₂] (sol=MeCN, MeOH). Complex 3a reacts with pyridine to give [Rh(CO)(py)(COMe)I₂]₂ and [Rh(CO)(py)₂(COMe)I₂] and with chelating diphosphines to give [Rh(Ph₂P(CH₂)_nPPh₂)(COMe)I₂] (n=2, 3, 4). Addition of MeI to [Ir(CO)₂(NCMe)I] is two orders of magnitude slower than to [Ir(CO)₂I₂]⁻. A mechanism for the reaction of 1 with MeI in MeCN is proposed, involving initial bridge cleavage by solvent to give [Rh(CO)₂(NCMe)I] and participation of the anion [Rh(CO)₂I₂]⁻ as a reactive intermediate. The possible role of neutral Rh(III) species in the mechanism of Rh-catalysed methanol carbonylation is discussed.     

Kinetics and mechanism of the oxidative addition of iodomethane to β-diketonatobis(triphenylphosphite)rhodium(I) complexes

The kinetics and mechanism of the oxidative addition of CH₃I to [Rh(β-diketone)(P(OPh)₃)₂] complexes was studied in acetone medium at various temperatures. The experimental rate law is R = k[Rh(β-diketone)(P(OPh₃)₂][CH₃I]. The order of the effect of the β-diketone on the reactivity of the complexes is acac >; BA >; DBM >; TFAA >; TFBA >; HFAA indicating that electronegative substituents of the β-diketone decrease the reactivity of the complexes towards oxidative addition reactions. The volume of activation for some of the reactions was determined in various solvents. The large negative values of the volume and entropy of the activation indicated a mechanism which occurs via a polar transition state.     

Equilibrium, solid state behavior and reactions of four and five co-ordinate carbonyl stibine complexes of rhodium. Crystal Structures of trans-[Rh(Cl)(CO)(SbPh3)2], trans-[Rh(Cl)(CO)(SbPh3)3] and trans-[Rh(I)2(CH3)(CO)(SbPh3)2]

The crystal structures of the four-coordinate trans-[Rh(Cl)(CO)(SbPh₃)₂] (1) and the five-coordinate trans-[Rh(Cl)(CO)(SbPh₃)₃] (2) are reported, as well as the unexpected oxidative addition product, trans-[Rh(I)₂(CH₃)(CO)(SbPh₃)₂] (3), obtained from the reaction of 2 with CH₃I. The formation constants of the five-coordinate complex were determined in dichloromethane, benzene, diethyl ether, acetone and ethyl acetate as 163±8, 363±10, 744±34, 1043±95 and 1261±96 M⁻¹, respectively. While coordinating solvents facilitate the formation of the five-coordinate complex, the four-coordinate complex could be obtained from diethyl ether due to the favorable low crystallization energy. The tendency of stibine ligands to form five-coordinate rhodium(I) complexes is attributed mainly to electron deficient metal centers in these systems, with smaller contributions by the steric effects. The average effective cone angle for the SbPh₃ ligand in the three crystallographic studies was determined as 139° with individual values ranging from 133 to 145°.     

Synthesis and characterisation of ferrocene-containing β-diketonato complexes of rhodium(I) and rhodium(III)

The synthesis of new β-diketonato rhodium(I) complexes of the type [Rh(FcCOCHCOR)(CO)₂] and [Rh(FcCOCHCOR)(CO)(PPh₃)] with Fc=ferrocenyl and R=Fc, C₆H₅, CH₃ and CF₃ are described. ¹H, ¹³C and ³¹P NMR data showed that for each of the non-symmetric β-diketonato mono-carbonyl rhodium(I) complexes, two isomers exist in solution. The equilibrium constant, K_c, which relates these two isomers in an equilibrium reaction, are concentration independent but temperature and solvent dependent. Δ_rG, Δ_rH and Δ_rS values for this equilibrium have been determined and a linear relationship between solvent polarity on the Dimroth scale and K_c exists. The relationship between RhP bond lengths, d(RhP), and ³¹P NMR peak positions as well as coupling constants ¹J(³¹P¹⁰³Rh) has been quantified to allow calculation of approximate d(RhP) values. Variations in d(RhP) for [Rh(RCOCHCOR′)(CO)(PPh₃)] complexes have also been related to the group electronegativities (Gordy scale) of the terminal β-diketonato R groups trans to PPh₃. A measure of the electron density on the rhodium centre of [Rh(RCOCHCOR′)(CO)(PPh₃)] may be expressed in terms of the IR carbonyl stretching wave number, ν(CO), the sum of the group electronegativities of the R and R′ groups, (χ_R+χ_R′), or the observed pK_a^′ values of the free β-diketones RCOCH₂COR^′. An empirical relationship between ν(CO) and either pK_a^′ or (χ_R+χ_R′) has also been quantified.     

Efficient synthesis of the cyclometalated complex fac-[Rh(ppy)3] (ppy = 2-phenylpyridinato)

A new convenient high-yield synthesis of the tris-cyclometalated complexes fac-[Rh(ppy)₃] (4; ppy = 2-phenylpyridinato) was developed. Complex 4 was prepared in a kind of one-pot synthesis starting from in situ prepared [Rh(acac)(coe)₂] (2) which was heated in refluxing 2-phenylpyridine for a short time. After purification by filtration over alumina, compound 4 was obtained in yields of 65%. Also [Rh(acac)(ppy)₂] (3) was prepared in a similar manner by oxidative addition of Hppy in refluxing toluene in high yields. In contrast to previous findings with the analogous iridium compounds, there was not any hint at the formation of the isomer mer-[Rh(ppy)₃] using similar reaction conditions as applied for iridium. Furthermore the compound [{Rh(μ-Cl)(ppy)₂}₂] (5) was prepared from [{Rh(μ-Cl)(coe)₂}₂] (1) and Hppy in refluxing toluene in nearly quantitative yield.     

Synthesis and isocyanate insertion reactions of tungsten(IV) imido complexes formed from W(CO)(acac)(N3)(PMe3)3 with azide as the oxidant

Addition of excess trimethylphosphine and a halide source to a solution of W(CO)(acac)₂(η²-L) (L = NCPh and OCMe₂) leads to displacement of L and one acetylacetonate chelate to produce electron-rich, seven-coordinate complexes of the formula W(CO)(acac)(X)(PMe₃)₃ (X = Cl, Br, and I). Use of NaN₃ instead of a halide source leads primarily to loss of carbon monoxide and dinitrogen, and protonation from adventitious water yields the cationic imido complex [W(NH)(acac)(PMe₃)₃]⁺. Heating [W(NH)(acac)(PMe₃)₃]⁺ in aromatic isocyanates at high temperature results in isocyanate insertion into the NH imido bond to form new C-N bonds. An alternate route to related imido complexes involves heating [W(O)(acac)(PMe₃)₃]⁺ with phenyl isocyanate at high temperatures to yield the substituted imido complex [W(NPh)(acac)(PMe₃)₃]⁺.     

Reaction of a rhodium(I) carbonyl complex of a para-dimethylaminophenyl substituted diphosphine with methyl iodide and hydrogen iodide

Reaction of [Rh(CO)₂](μ-Cl)]₂ with bis-1,2-(di{4-dimethylaminophenyl)phosphino-ethane (L) gives the monomeric Rh(I) complex of type cis-[RhCl(L)(CO)] that was separated from a side product of type [Rh(L)₂]Cl, and characterised by X-ray crystallography. This complex reacts with methyl iodide at high temperature to give the Rh(III) acetyl complex, [Rh(I)₂(C(O)Me)(L)], which was also structurally characterised by X-ray crystallography. There is no sign of quaternisation of the dimethylamino groups under these conditions. This complex is soluble in organic solvent and insoluble in the polar media used in methanol carbonylation (AcOH/H₂O/MeOH). However, in the presence of HI, this complex is readily soluble in AcOH/H₂O/MeOH, in contrast to [Rh(I)₂(C(O)Me)(dppe)] and most other Rh-acetyl complexes of diphosphine ligands.     

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.     

Synthesis, characterization and reactivity of polypyridyl ruthenium(II) carbonyl complexes with phosphine derivatives: Ruthenium-carbon bond labilization based on steric and electronic effects

Ruthenium phosphine complexes with a CO ligand [Ru(tpy)(PR₃)(CO)Cl]⁺ (tpy = 2,2′:6′,2″-terpyridine, R = Ph or p-tolyl), were prepared by introduction of CO gas to the corresponding dichloro complexes at room temperature. New carbonyl complexes were characterized by various methods including structural analyses. They were shown to release CO following the addition of several N-donors to form the corresponding substituted complexes. The kinetic data and structural results observed in this study indicated that the CO release reactions proceeded in an interchange mechanism. The molecular structures of [Ru(tpy)(PPh₃)(CO)Cl]PF₆, [Ru(tpy)(P(p-tolyl)₃)(CO)Cl]PF₆ and [Ru(tpy)(PPh₃)(CH₃CN)Cl]PF₆ were determined by X-ray crystallography.     

A rhodium(I) complex containing a mixed donor `P2N' tridentate ligand

The reaction of 2-(diphenylphosphino)-N-[2-(diphenylphosphino)benzylidene]benzeneamine (PNCHP) with 0.5 equivalents of [{RhCl(1,5-cyclooctadiene)}₂] affords the extremely, air-sensitive compound, [RhCl(PNCHP-κ³P,N,P)]. This reacts with carbon monoxide to afford [RhCl(CO)(PNCHP-κ³P,N,P)] which rearranges in dichloromethane solution to [Rh(CO)(PNCHP-κ³P,N,P)]Cl · HCl. The single crystal structure of [Rh(CO)(PNCHP-κ³P,N,P)]Cl · HCl shows the Rh to be in a square planar environment with the HCl molecule held via hydrogen bonding in the lattice. NMR experiments show the coordinated chloride in [RhCl(PNCHP-κ³P,N,P)] can be substituted with tetrahydrofuran, acetonitrile or triphenylphosphine and the complex undergoes oxidative addition with dichloromethane to yield [Rh(CH₂Cl)Cl₂(PNCHP-κ³P,N,P)].     

The synthesis of some polyether bridged diphosphines and their reaction with Rh(COD)acac

The polyether bridged diphosphines,

(n = 1,2) have been prepared in 60–70% yield by reduction of the corresponding diphosphinedioxides with Si₂Cl₆ or (i-Bu)₂AlH. These diphosphinedioxides have been prepared in 75–90% yield by reaction of two equivalents of the appropriate

with one equivalent of di- and triethylene glycol ditosylate.In general, reaction between the diphosphines, Rh(COD)acac and HClO₄ gives a mixture of species, cis-[Rh(COD)($\text{PP}$)] [ClO₄] being the main complex. This complex reacts with CO to η³-trans- [$\text{Rh(CO)(}\text{PO}$$\text{P}$)] [ClO₄].     

The structure of 2-carboxyquinolinatobis(triphenylphosphite)rhodium(I)

2-Carboxyquinolinatobis(triphenylphosphite)rhodium (I) was prepared by means of the following reaction: [Rh(Qin)(CO)₂] + 2P(OPh)₃→ [Rh(Qin)(P(OPh)₃)₂] + 2CO It crystallizes in the triclinic space groupP] witha = 12.406,b = 18.702,c = 9.547 Å, α = 76.36, β = 111.35, γ = 97.88^o and Z = 2. The structure was determined from 4520 observed reflections. the final R value was 0.051. The RhP bond distances may indicate (although the difference is only about 3σ) that the nitrogen atom the chelate ring has the largest trans influence. The chelate ring is significantly folded along the N---O axis.     

A new tricarbonyl fac-[M(acac)(isc)(CO)3] complex (M = Re, Tc) with acetylacetonate (acac) and isocyanide (isc) in a 2+1 combination

The synthesis and characterization of the neutral 2+1 mixed ligand complex fac-Re(CO)₃(acac)(isc) (4) with acetylacetonate (acac) as the bidentate ligand and an isocyanide (the isocyanocyclohexane, isc) as the monodentate ligand is described. The synthesis of 4 proceeds through the intermediate formation of the fac-Re(acac)(H₂O)(CO)₃ precursor complex 2. Complex 4 was characterized by elemental analysis, spectroscopic methods, and X-ray crystallography showing a distorted octahedral arrangement of the ligands around Re. At technetium-99m level, the corresponding fac-^99mTc(acac)(isc)(CO)₃ complex 5 was obtained in high yield by reacting the fac-^99mTc(acac)(H₂O)(CO)₃ precursor complex 3 with isocyanocyclohexane and its structure was established by chromatographic comparison with the prototypic rhenium complex using high performance liquid chromatography.     

Metal chelates with biological activity. Part 4. Solution properties of iron(III)-histidinehydroxamic acid

Reactions of carbon monoxide with iron(II) diethyldithiocarbamate and iron(II) ethylxanthate were followed using solution IR spectroscopy. In DMF and CH₃CN solutions, the only Fe—dithiocarbamate—carbon monoxide complex observed was cis-[Fe(CO)₂(dedtc)₂]. This complex formed rapidly and appeared to be very stable, resisting displacement of the coordinated CO molecules by other ligands. Fe(exa)₂ showed very little coordination of CO in DMF solution, but in CH₃CN solution formed the complex cis-[Fe(CO)₂(exa)₂] rapidly via the monocarbonyl intermediate [Fe(CO)(exa)₂CH₃CN]. In CHCl₃ solution, in the presence of CO and added bases, a series of complexes, [Fe(CO)(exa)₂L], where L = pyridine, pyrrolidine, diethylamine and triphenylphosphine, was formed. However, with the exception of [Fe(CO)(exa)₂(ø₃P)], these monocarbonyl complexes were unstable with respect to disproportionation to cis-[Fe(CO)₂(exa)₂] and [Fe(exa)₂L₂]. No mixed-ligand monocarbonyl complexes were observed with Fe(dedtc)₂.     

Coordination of 4-mercapto-1,2-dithiole-3-thione heterocycles to ruthenium(II) and molybdenum(VI) centres

Deprotonation of 4-mercapto-1,2-dithiole-3-thiones with NEt₃ followed by reaction with [Ru(H)(Cl)(CO)(PPh₃)₃] affords virtually quantitative yields of turquoise [Ru(H)(RC₃S₄)(CO)(PPh₃)₂] (R = Ph, Mes) in which the heterocycle is bound as a bidentate uninegative ligand through the two exocyclic sulfur atoms. The presence of both possible isomers in each case is indicated by NMR spectroscopy. Reaction of the 4-mercapto-1,2-dithiole-3-thiones with [MoO₂(acac)₂] results in displacement of the acac ligands and formation of [MoO₂(RC₃S₄)₂]. The crystal structures of [Ru(H)(MesC₃S₄)(CO)(PPh₃)₂] and [MoO₂(MesC₃S₄)₂] have been determined.     

Novel rhodium complexes containing a bulky iminophosphine ligand and their use as catalysts for the hydroboration of vinylarenes

Addition of o-Ph₂PC₆H₄CHN-2,6-ⁱPr₂C₆H₃ (1) to [RhCl(coe)₂]₂ (coe = cis-cycloctene) gave several new iminophosphino rhodium(I) complexes including [Rh(κ²-o-Ph₂PC₆H₄CHN-2,6-ⁱPr₂C₆H₃)(μ-Cl)]₂ (2). Addition of 1 to Rh(acac)(coe)₂ (acac = acetylacetonato) gave [Rh(acac)(κ²-o-Ph₂PC₆H₄CHN-2,6-ⁱPr₂C₆H₃)] (3) in yields of up to 75%. Complex 3 has been examined for its ability to catalyze the hydroboration of a series of vinyl arenes. Reactions using catecholborane and pinacolborane seem to proceed largely through a dehydrogenative borylation mechanism to give a number of boronated products.     

Structural properties and inversion mechanisms of [Rh(dippe)(μ-SR)]2 complexes

Several new bis-thiolate complexes of the type [Rh(dippe)(μ-SR)]₂ where R=H, methyl, cyclohexyl, o-biphenyl, and phenyl, or (SR)₂SCH₂CH₂CH₂S have been synthesized and characterized by NMR spectroscopy and single crystal X-ray diffraction. All [Rh(dippe)(μ-SR)]₂ complexes except [Rh(dippe)(μ-SPh)]₂ exhibit bent geometries, while the orientation of the thiolato substituents changes with increasing steric bulk. ¹H and ³¹P NMR spectroscopies indicate that both ring inversion and sulfur inversion occur among the members of the series, which allows them to access several isomeric forms when they are in solution. ³¹P NMR spectroscopy indicates that sulfur inversion in [Rh(dippe)(μ-SH)]₂, [Rh(dippe)(μ-Sbiphenyl)]₂, and [Rh(dippe)(μ-SPh)]₂ is a non-dissociative process.