Interactions of Rh(III)-dihydrido-bis(phosphine) complexes with semicarbazones

Interaction of cis,trans,cis-[Rh(H)2(PR3)2(acetone)2]PF6 complexes (R = aryl or R3 = Ph2Me, Ph2Et) under H2 with E-semicarbazones gives the Rh(III)-dihydrido-bis(phosphine)-semicarbazone species cis,trans-[Rh(H)2(PR3)2{R'(R' ')C=N-N(H)CONH2}]PF6, where R' and R' ' are Ph, Et, or Me. The complexes are generally characterized by elemental analysis, 31P{1H} NMR, 1H NMR, and IR spectroscopies, and MS. X-ray analysis of three PPh3 complexes reveals chelation of E-semicarbazones by the imine-N atom and the carbonyl-O atom. In contrast, the corresponding reaction of [Rh(H)2(PPhMe2)2(acetone)2]PF6 with acetophenone semicarbazone gives the ortho-metalated-semicarbazone species cis-[RhH(PPhMe2)2{o-C6H4(Me)C=N-N(H)CONH2}]PF6. The X-ray structure of E-propiophenone semicarbazone is also reported. Rhodium-catalyzed, homogeneous hydrogenation of semicarbazones was not observed even at 40 atm H2.     

Isocyanide complexes of rhodium,part 41,2). η5-pentamethylcyclopentadienyl-rhodium (III) compounds

Summary The complexes Rh(⁵-C₅Me₅)(CNR)Cl₂, [Rh(⁵ - C₅Me₅)(CNR)₂Cl][PF₆], (R = Me, Et, i-Pr, t-Bu, C₆H₁₁, , p-CIC6H4 and 1-naphthyl), and [Rh(⁵-C⁵Me⁵)(CNR)₃][PF₆] (R = Et, i-Pr and t-Bu)] have been prepared by treatment of [Rh(⁵-C₅Me₅)Cl₂]₂ with RNC in the presence of [PF₆]^– (as appropriate). These complexes do not react with alcohols or amines to yield carbenes, but withm-MeC₆H₄SNa and NaS₂CNR₂, the species Rh(⁵-C₅H₅)(CNEt)(SC₆M₄Me-m)₂ and [Rh(⁵-C₅Me₅)(CNR)(S₂CNR₂)][PF₆] (R = Me, R¹ = Me or Et; R =p-ClC₆H₄, R¹ = Me) are formed. Treatment of [Rh(⁵-C₅H₅)(CNR)₂Cl][PF₆] with NaBH₄ gave low yields of compounds tentatively formulated as [Rh(⁵-C₅Me₅)(CNR)₂(BH₄)][PF₆] (R = Me or Et).Reprints of this article are not available.     

Isocyanide complexes of rhodium,part 31,2. Tetrakisisocyanide species four- and five-coordinate mixed isocyanide-tertiary phosphine complexes,and some oxidative-additions

Summary The complexes [Rh(CNR)₄][PF₆] (R = Et, C₆H₁₁,-NH₂C₆H₄ or I-C₁₀H₇),trans-[Rh(CNR)₂(PRR ₂ ^" )₂][PF₆] (R = R = Ph, R = Et, C₆H₁₁, -NH₂C₆H₄ or 1-C₁₀H₇; R= Me, R = Ph or R= Ph, R= Me, R= 1-C₁₀H₇) and [Rh(CNR)₃(PPh₃)₂][PF₆] (R = Me, Et or C₆H₁₁) have been prepared by treatment of [Rh(CO)₂Cl]₂ or Rh(CO)(PPh₃)₂Cl with RNC, or of [Rh(CNC₁₀H₇)₄][PF₆] with PRR₂ (R, R = Me, Ph). Addition of -ClC₆H₄NC to [Rh(CNEt)₂(PPh₃)₂][PF₆] gives [Rh(CNEt)₂(CNC₆H₄Cl-)(PPh₃)₂][PF₆]. Reactions of [Rh(CNR)₄][PF₆] and [Rh(CNR)₂(PPh₃)₂][PF₆] (R = Me, Et, C₆H₁₁ or 1-C₁₀H₇) with halogens, MeI, McCOCl, CF₃I, HgCl₂ and SO₂, are discussed briefly. The i.r. and¹H n.m.r. spectra show that the products aretrans-[ Rh(CNR)₄XY][PF₆] andtrans-[Rh(CNR)₂(PPh₃)2XY][PF₆].     

Monocarbonyl cationic rhodium(I) complexes

Summary The preparations and characterisation of cationic complexes of the type [Rh(CO)(MeCN)(PR₃)₂]ClO₄, [Rh(CO)L(PR₃)₂]ClO₄ (L=py or 2-MeOpy), [Rh(CO)(L-L)(PR₃)₂]ClO₄ (L-L = bipy or phen) and [Rh(CO)(PR₃)₃]ClO₄ with PR₃ = P(p-YC₆H₄)₃ (Y=Cl, F, Me or MeO) are described.     

Iridium(iii)-(hydrido)cyclometallated-imine complexes and metal-promoted hydrolytic cleavage of imines

The room temperature reaction of the complex cis,trans,cis-[Ir(H)₂(PPh₃)₂(Solv)₂]PF₆ (Solv is a solvent) with the imine PhCH₂N=CHPh in acetone generates (with loss of H₂) the orthometallated complex [Ir(H){PhCH₂N=CH(o-C₆H₄)}(PPh₃)₂(Me₂CO)]PF₆ (3) containing a five-membered cyclometallated imine moiety. In MeOH, the reaction at an imine : Ir ratio = 1 leads to the corresponding MeOH analog of 3, while with excess imine, the mixed orthometallated imine/bezylamine complex [Ir(H){PhCH₂N=CH(o-C₆H₄)}(PPh₃)₂(PhCH₂NH₂)]PF₂ (4) is formed; the source of the coordinated amine is an Ir-promoted hydrolysis of the imine, the water likely coming from imine. Complexes 3 and 4 are fully characterized by elemental analysis, ¹H and ³¹P{¹H} NMR spectroscopy, and X-ray crystal structure analysis.     

Cleavage of the carbon-silicon bonds in trimethylsilylacetylenes by trans[(PR3)2PtX(R′OH)]PF6 cations and formation of cationic alkoxycarbene complexes of platinum(II)

Cationic alkoxycarbene complexes of platinum(II) have been isolated in the reactions of trans-[(PR₃)₂PtX(R′OH)]PF₆ (X  H or Me; R′  Me or Et) with Me₃SiCCR′′ (R′′  H, Me or SiMe₃). In these reactions cleavage of the carbon-silicon bond by the nucleophilic attack of alcohol has been observed. These carbene complexes have been characterized by elemental analyses and by IR, ¹H and ¹³C NMR spectral data. ¹³C NMR chemical shift data for carbene carbon atoms suggest that the carbene carbon may be very positively charged.     

Substituted dipyridylpyridazine rhodium(III) complexes

3,6-Bis(2-pyridyl)pyridazine derivatives (n-dppn) react with hydrated rhodium(III) chloride and bromide (prepared in situ) to give cis-[Rh(n-dppn)₂Cl₂]PF₆·xH₂O (n = 5, 6, 7, 8) and cis-[Rh(n-dppn)₂Br₂]Br·xH₂O (n = 5, 7) complexes, which have been characterized by elemental analyses, conductivity measurements, i.r., electronic and ¹H- and ¹³C-n.m.r. spectra.     

Reactions of [Re(NO)2(PR3)2][BArF 4] complexes with phenylacetylene

The reaction of [Re(NO)₂(PR₃)₂][BAr^F ₄] (R = cyclo-C₆H₁₃ (1a), Prⁱ (1b); [BAr^F ₄]^– = [B(3,5-(CF₃)₂C₆H₃)₄]) with phenylacetylene in the presence of a non-nucleophilic base, like 2,6-bis(tert-butyl)pyridine (BTBP) or Bu^tOK, affords the phenylethynyl complexes [Re(CCPh)(NO)₂(PR₃)₂] (R = cyclo-C₆H₁₃ (2a); Prⁱ (2b)) in moderate yields. In the absence of a base, complexes 1a and 1b are transformed into the compounds [Re(CCPh)(CH=C(Ph)ONH)(NO)(PR₃)₂][BAr^F ₄] (3a and 3b, respectively). The structure of complex 3a was confirmed by X-ray diffraction analysis. The latter reaction is proposed to be initiated by deprotonation of the terminal alkyne H atom by the bent nitrosyl ligand followed by the subsequent 1,3-dipolar addition of the ReN(H)O moiety to phenylacetylene.     

Reactions of 1,4-diaza-3-methylbutadien-2-ylpalladium(II) derivatives with chloro-bridged rhodium(I) complexes

The reactions of the organometallic 1,4-diazabutadienes, RN=C(R′)C(Me)=NR″ [R = R″ = p-C₆H₄OMe, R′ = trans-PdCl(PPh₃)₂ (DAB); R = p-C₆H₄OMe, R″ = Me, R′ = trans-PdCl(PPh₃)₂ (DAB^I; R = R″ = p-C₆H₄OMe, R′ = Pd(dmtc)-(PPh₃), dmtc = dimethyldithiocarbamate (DAB^II); R = R″ = p-C₆H₄OMe, R′ = PdCl(diphos), diphos = 1,2-bis(diphenylphosphino)ethane (DAB^III)] with [RhCl(COD)]₂ (COD = 1,5-cyclooctadiene, Pd/Rh ratio = $\text{1}\text{2}$) depend on the nature of the ancillary ligands at the Pd atom in group R′. In the reactions with DAB and DAB^I transfer of one PPh₃ ligand from Pd to Rh occurs yielding [RhCl(COD)(PPh₃)] and the new binuclear complexes [Rh(COD) {RN=C(R?)-C(Me)=NR″}], in which the diazabutadiene moiety acts as a chelating bidentate ligand. Exchange of ligands between the two different metallic centers also occurs in the reaction with DAB^II. In this case, the migration of the bidentate dmtc anion yields [Rh(COD)Pdmtc] and [Rh(COD) {RN=C(R?)C(Me)=NR″}]. In contrast, the reaction with DAB^III leads to the ionic product [Rh(COD)- (DAB^III)][RhCl₂(COD)], with no transfer of ligands. The cationic complex [Rh(COD)(DAB^III)]⁺ can be isolated as the perchlorate salt from the same reaction (Pd/Rh ratio = 1/1) in the presence of an excess of NaClO₄. In all the binuclear complexes the coordinated 1,5-cyclooctadiene can be readily displaced by carbon monoxide to give the corresponding dicarbonyl derivatives. The reaction of [RhCl(CO)₂]₂ with DAB and/or DAB^I yields trinuclear complexes of the type [RhCl(CO)₂]₂(DAB), in which the diazabutadiene group acts as a bridging bidentate ligand. Some reactions of the organic diazabutadiene RN=C(Me)C(Me)=NR (R = p-C₆H₄OMe) are also reported for comparison.     

Dicarbonyl dithio ligand complexes of tungsten(II)

Reaction of LWI(CO)_n [L=hydrotris(3,5-dimethylpyrazol-1-yl)borate, n=2, 3] with NH₄[S₂PR₂] [R=OEt, OPrⁱ, (−)-mentholate (R*), Ph] in acetonitrile or THF results in the formation of the dithio ligand complexes LW(S₂PR₂-S)(CO)₂. The yellow–orange, diamagnetic complexes exhibit IR spectra featuring two ν(CO) bands at ca. 1950 and 1840 cm⁻¹ and ¹H-NMR spectra consistent with fluxional behavior in solution. Crystallographic characterisation of LW{S₂P(OPrⁱ)₂-S}(CO)₂ revealed a six-coordinate, distorted octahedral complex composed of a tungsten center coordinated by a monodentate dithiophosphate ligand, two cis carbonyl ligands, and a facial, tridentate L ligand. Unlike analogous complexes bearing strictly monodentate sulfur donor ligands, the LW(S₂PR₂)(CO)₂ complexes undergo reactions with oxygen atom donors to produce (carbonyl)oxo complexes of the type LWO(S₂PR₂-S)(CO).     

Platinum thiosemicarbazide and thiourea complexes: the crystal structure of [PtCl(dppe){SC(NHMe)NHNMe2-S}](PF6) and the influence of intramolecular hydrogen bonding on ligand co-ordination mode

The reaction of [PtCl₂(dppe)] [dppe=1,2-bis(diphenylphosphino)ethane] with two equivalents of the thioureas NHRC(S)NHR (R=H, Me, Et) in the presence of NH₄PF₆ led to substitution of both chlorides and formation of the complexes [Pt(dppe){SC(NHR)₂}₂](PF₆)₂ (1a, R=H; 1b, R=Me; 1c, R=Et). In contrast, the reaction of [PtCl₂(dppe)] with one equivalent of the potentially bidentate thiosemicarbazides NHRC(S)NHNR′₂ (R=Me, R′=H; R=Et, R′=H; R=Ph, R′=H; R=Me, R′=Me) in the presence of NH₄PF₆ led to substitution of only one chloride and formation of the complexes [PtCl(dppe){SC(NHR)NHNR₂′-S}](PF₆) (2a, R=Me, R′=H; 2b, R=Et, R′=H; 2c, R=Ph, R′=H; 2d, R=Me, R′=Me). An X-ray analysis of complex 2d revealed that an intramolecular N–H⋯Cl hydrogen bond [N(2)⋯Cl(1)=3.29(2) Å] helps to stabilise the monodentate co-ordination mode. The chloride ligand can be abstracted from complex 2d by treatment with TlPF₆, and this reaction led to formation of [Pt(dppe){SC(NHMe)NHNMe₂-S,N}](PF₆)₂ 3d. Reaction of [PtCl₂(dppe)] with unsubstituted thiosemicarbazide NH₂C(S)NHNH₂ in the presence of NH₄PF₆ resulted in a mixture of products containing mono- and bidentate co-ordinated ligands, [PtCl(dppe){SC(NH₂)NHNH₂-S}](PF₆) 2e and [Pt(dppe){SC(NH₂)NHNH₂-S,N}](PF₆)₂ 3e. [PtCl₂(dppe)] also reacts with two equivalents of NHMeC(S)NHNMe₂ in the presence of NH₄PF₆ to yield [Pt(dppe){SC(NHMe)NHNMe₂-S}₂](PF₆)₂ 1d, in which the thiosemicarbazide is acting as an S-donor, directly analogous to the thiourea ligands in complexes 1a–c.     

IR,Multinuclear-NMR,and Structural Studies on [WH(CO)2(NO)(PR3)2]: cis-Influence of Phosphorus Ligands on Hydride Character

A thorough IR and ¹H-, ¹³C-, ³¹P-, ¹⁸³W-NMR spectroscopic, and X-ray structural study was carried out on complexes of the type trans, trans-[WH(CO)₂(NO)(PR₃)₂], (R = Et, Me, Ph, i-PrO, MeO, and PhO). Linear correlations could be found between Tolman's parameter X and v(CO), v(WH), v(NO), δ(¹³C) (CO), as well as 1n(k), k being the H/D exchange rate constant for the hydride in CD₃OD. The ¹J(¹⁸³W,³¹P), ²J(³¹P,¹H), and ²J(³¹P,¹³C) as well as the ¹J(¹⁸³W,¹H) values are related to the electronegativity of the R groups on the phosphorus ligands. This is also indicated by EHT calculations of s-orbital populations of appropiate W model complexes. The X-ray structures of [WH(CO)₂(NO)(PR₃)₂] (R = Me, Ph, and MeO) were determined. Minor differences were observed in the W? P bond lenghts and in the P? W? P and C? W? C angles. No obvious relationship between X-ray data and spectroscopic parameters could be found. All three structures reveal a bending of both the CO and PR₃ ligands towards the hydride atom. The total octahedral distortion is remarkably constant (25.6, 29.4, and 27.0° tilt, respectively), although the ligands individually are very different. This is attributed to redistribution of π-electron density between CO and PR₃ groups toward the central W-atom in the three complexes.     

Preparation and properties of palladium(II) and rhodium(I) complexes containing bidentate phosphine sulphide and selenide ligands

Summary The synthesis and properties of cationic complexes of general formula [ML₂{CH₂(Ph₂PE)₂}]BF₄, where M = Pd^II and Rh^II, L₂ = ³-MeC₃H₄, {P(O)(OR)₂}₂H (R = Me, Et), COD, (CO)₂, (CO)PPh₃ and E = S, Se are described. The methylene proton of the coordinated phosphine sulphide or selenide ligands react with strong bases as BuLi in n-hexane or NaH in THF, to give neutral complexes of the type [ML₂{CH(Ph₂PE)₂}], where M = Pd^II, Rh^I; L₂ = ³-MeC₃H₄, COD and E = S, Se. The complexes have been characterized by elemental analyses, molar conductivities, i.r., ¹H n.m.r. and ³¹P{¹H} n.m.r. spectroscopy.     

Interaction between cobaltocenium and decamethylcobaltocenium salts and Ph3ELi (E = Si,Ge, Sn)

Reactions of cobaltocenium salts [(C₅R₅)₂Co]PF₆ (R = H, Me) with Ph3ELi (E = Si, Ge, Sn) and with Ph₂SbLi mainly follow two pathways (nucleophilic addition and one-electron reduction), yielding cobalt cyclopentadiene-cyclope ntadienyl complexes (⁴-Ph₃EC₅R₅)(⁵-C₅R₅)Co (R = H, E = Si, Ge, Sn; R = Me, E = Si) and cobaltocenes (C₅R₅)₂Co (R = H, Me), respectively. The contribution of nucleophilic addition of Ph₃ELi decreases in the order of elements Si > Ge > Sn and when hydrogen atoms are replaced by methyl groups in the initial cobaltocenium salt. Thermal decomposition of cobalt cyclopentadiene-cyclopentadienyl complexes results in substituted cobaltocenes.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya. No. 10, pp. 2557–2560, October, 1996.     

Cyclopentadienylruthenium(II) dialkyldithiophosphate and diphenyldithiophosphinate complexes

Summary Cyclopentadienylruthenium(II) dialkyldithiophosphate and diphenyldithiophosphinate complexes, [RuCp(SSPR₂)-(PR₃)J (R = OEt, OPr-n, OPr-i, OBu-n, Ph; R = Ph or C₆H₄Me-p; n = 1 or 2) have been prepared and characterized by elemental analysis and n.m.r. (¹H and ³¹P) spectral data. The dithio ligand, where n = 1 or 2, behaves in a chelating bidentate and monodentate fashion, respectively.     

Synthesis and structure of dimeric Rh-bis(tertiary phosphine) complexes,exceptionally useful synthetic precursors

Removal of the MeOH and hydrogen from the known cis,trans,cis-Rh^III-dihydrido complexes 〚Rh(H)₂(PR₃)₂(MeOH)₂〛PF₆ (R = Ph, p-tolyl) results in formation of the dimeric species 〚Rh₂(PR₃)₄〛〚PF₆〛₂; X-ray analysis shows the complexes to be 〚(Ph₃P)Rh(μ-PhPPh₂)〛₂〚PF₆〛₂ (and the p-tolyl analogue) containing bridged η⁶-arene moieties, while ¹H and ¹³C NMR data in CD₂Cl₂ provide evidence for η⁴-coordination of the arene within the dimer. In more strongly coordinating solvents, formation of cis-〚Rh(PR₃)₂(solvent)₂〛PF₆ is observed, while formation of 〚(PR₃)₂Rh(η⁶-toluene)〛PF₆ is evident in toluene solution, and this exists in equilibrium with the bis(solvent) species in the presence, for example, of acetone or MeOH. At ambient conditions, none of the arene-containing complexes effected catalytic H₂-hydrogenation of toluene.     

Influence of the phosphine ligands in the 1H and 31P NMR behaviour of [(η3-allyl)Py(phophine)Cl] complexes

The ¹H and ³¹P NMR spectra of (η³-allyl)Pt(PR₃)Cl] (PR₃ = PMe₃, PCy₃, P-t-Bu₃, P-n-Bu₃, PPh₃, PPh₂Me, PPhMe₂ and P(p-Tol)₃) complexes in chloroform have been studied. The results suggest that there is bonding interaction between the phosphine and the allyl group via central metal atom.     

Some diolefin complexes of iridium(I) and a trans-influence series for the complexes [IrCl(cod)L]

A high-yield synthesis of [IrCl(cod)]₂ (cod = 1,5-cyclooctadiene) is described. The ¹H and ¹³C NMR spectra of a number of complexes [IrCl(cod)L] are interpreted in terms of a trans-effect series Cl^? < sym-collidine < 2-picoline < PCy₃ < P-i-Pr₃ < Pet₃ ～ AsPh₃ < PMe₂Ph < PMePh₂ < PPh₂ <P(MeO)Ph₂ < PClPh₂ < P(OPh)₃ < PCl₂Ph. Some ligand exchange reactions of [IrCl(cod)L] are discussed. A number of complexes of the type [Ir(cod)L_n]PF₆ (L = a variety of amines (n = 2) and phosphines (n = 2 or 3)) are described. Exchange reactions of the sort: [Ir(cod)(PR₃)₂]PF₆ + [Ir(cod)(py)₂]PF₆ ? [Ir(cod)(PR₃)Py]PF₆ are reported in which, surprisingly, the isolable mixed ligand complexes are the only detectable species at equilibrium (py = pyridine).     

Syntheses and Structures of trans-bis(Alkenylacetylide) Ruthenium Complexes

A series of ruthenium alkenylacetylide complexes trans-[Ru{C≡CC(=CH₂)R}Cl(dppe)₂] (R=Ph ( 1 a ), ^cC₄H₃S ( 1 b ), 4-MeS-C₆H₄ ( 1 c ), 3,3-dimethyl-2,3-dihydrobenzo[b]thiophene (DMBT) ( 1 d )) or trans-[Ru{C≡C-^cC₆H₉}Cl(dppe)₂] ( 1 e ) were allowed to react with the corresponding propargylic alcohol HC≡CC(Me)R(OH) (R=Ph ( A ), ^cC₄H₃S ( B ), 4-MeS-C₆H₄ ( C ), DMBT ( D ) or HC≡C-^cC₆H₁₀(OH) ( E ) in the presence of TlBF₄ and DBU to presumably give alkenylacetylide/allenylidene intermediates trans-[Ru{C≡CC(=CH₂)R}{C=C=C(Me)}(dppe)₂]PF₆ ([ 2 ]PF₆). These complexes were not isolated but deprotonated to give the isolable bis(alkenylacetylide) complexes trans-[Ru{C≡CC(=CH₂)R}₂(dppe)₂] (R=Ph ( 3 a ), ^cC₄H₃S ( 3 b ), 4-MeS-C₆H₄ ( 3 c ), DMBT ( 3 d )) and trans-[Ru{C≡C-^cC₆H₉}₂(dppe)₂] ( 3 e ). Analogous reactions of trans-[Ru(CH₃)₂(dmpe)₂], featuring the more electron-donating 1,2-bis(dimethylphosphino)ethane (dmpe) ancillary ligands, with the propargylic alcohols A or C and NH₄PF₆ in methanol allowed isolation of the intermediate mixed alkenylacetylide/allenylidene complexes trans-[Ru{C≡CC(=CH₂)R}{C=C=C(Me)}(dmpe)₂]PF₆ (R=Ph ([ 4 a ]PF₆), 4-MeS-C₆H₄ ([ 4 c ]PF₆). Deprotonation of [ 4 a ]PF₆ or [ 4 c ]PF₆ gave the symmetric bis(alkenylacetylide) complexes trans-[Ru{C≡CC(=CH₂)R}₂(dmpe)₂] (R=Ph ( 5 a ), 4-MeS-C₆H₄ ( 5 c )), the first of their kind containing the dmpe ancillary ligand sphere. Attempts to isolate bis(allenylidene) complexes [Ru{C=C=C(Me)R}₂(PP)₂]²⁺ (PP=dppe, dmpe) from treatment of the bis(alkenylacetylide) species 3 or 5 with HBF₄ ⋅ Et₂O were ultimately unsuccessful.     

Zur Synthese von Tris(diorganylphosphino)phosphanen mit Substituenten geringen Raumbedarfs

Synthesis of Tris(diorganylphosphino)phosphines with Substituents of Low Steric Hindrance The reaction of M^IP(SiMe₃)₂ (M^I = Li, Na, K) with diorganylchlorophosphines forms tris(diorganylphosphino)phosphines P(PR₂)₃ (R = Cy, Ph, i-Pr, n-Pr, Et, Me). In all cases, the stepwise formation reaction proceeds via di- and triphosphines resulting in iso-tetraphosphines which are stable in solution. Only the compounds with bulky substituents (R = Cy, Ph) can be isolated. By using quantumchemical procedures it is possible to get information about the pyramidal structure and the reaction behaviour. In agreement with these results orbitally controlled reactions occur where nucleophiles attack the central phosphorus atom.