Solution and solid state characterization of oxo-centered trinuclear iron(III) acetate complexes [Fe3(μ3-O)(μ-OAc)6(L)3]+

[Fe(3)(μ(3)-O)(μ-OAc)(6)(py)(3)][FeBr(4)](2)[py·H], complex (1), (OAc is acetate) was prepared from the reaction of FeBr(3) with pyridine in 1.2 molar aqueous HBr and 2.4 molar aqueous CH(3)COOH. Recrystallization of 1 in acetonitrile produced the [Fe(3)(μ(3)-O)(μ-OAc)(6)(py)(3)][FeBr(4)] complex (2). Both complexes were characterized by IR and (1)H NMR spectroscopies and their structures were studied using the single-crystal diffraction method. There is a lack of thorough characterization of the titled compounds in solution. Paramagnetic (1)H NMR is introduced as a good probe for the characterization of a family of titled compounds in solution when the L ligand coordinated to iron varies as: CH(3)OH, CH(3)CN, DMSO, H(2)O, py and acetone.     

Darstellung und struktur von Cp2ZrX2 und [Cp2Zr(X)(H2O)2]+ X−(X = toluolsulfonat)

Cp₂Zr(C₇H₇SO₃)₂ (C) can be prepared from Cp₂ZrCl₂ and silver toluenesulfonate in acetonitrile. Reaction of C with H₂O gives the ionic 18-electron species [Cp₂Zr(C₇H₇SO₃)(H₂O)₂]⁺ C₇H₇SO₃⁻ (D). The structures of both complexes have been determined by X-ray analyses. The Cp₂Zr units in C and D have the usual bent metallocene structure. The metal-bonded O atoms of the three additional ligands in D lie in a plane bisecting the plane of the Cp ligands, the C₇H₇SO₃ group being symmetrically flanked by the H₂O ligands. The H₂OZrOH₂ angle is 148°. On the other hand, the OZrO angle of 90° in C is relatively small for a Cp₂ZrX₂ compound.     

1,2,4-Triphospholyl gold(I) and copper(I) complexes: synthesis,crystal and molecular structures of [Cu(PMe3)2(μ-P3C2tBu2)(μ-I)Cu(PMe3)2], [Cu(PMe3)2(μ-P3C2tBu2)2Cu(PMe3)2] and [Au(η1-P3C2tBu2)2][Au(PEt3)2]

Treatment of K(P₃C₂^tBu₂) with Cu₂I₂ and PMe₃ gave the binuclear complex [Cu(PMe₃)₂(μ-P₃C₂^tBu₂)₂Cu(PMe₃)₂] via the isolated intermediate compound [Cu(PMe₃)₂(μ-P₃C₂^tBu₂)(μ-I)Cu(PMe₃)₂]. The reaction of K(P₃C₂^tBu₂) with [AuCl(PEt₃)] on the otherhand gave the cation:anion complex [Au(PEt₃)₂][Au(η¹-P₃C₂^tBu₂)₂]. All complexes were fully characterised by multinuclear spectroscopy and single crystal X-ray diffraction studies.     

Synthesis and structures of new heterometallic clusters [Fe2(MCp x )(CO)6(μ3-S)2] (M = Rh, Ir; Cp x = Cp*, C5H3But 2)

The reaction of the [Fe₂(CO)₆(μ-S)₂]^2? anion (prepared in situ by reduction of [Fe₂(CO)₆(μ-S₂)] with Na/K alloy) with [Cp″RhCl₂]₂ (Cp″ = η⁵-(1,3-Bu^t ₂)C₅H₃) and [Cp*Ir(CH₃CN)₃](CF₃SO₃)₂ (Cp^* is pentamethylcyclopentadienide) yielded new heterometallic clusters [Fe₂(MCp ^x )(CO)₆(μ₃-S)₂]. The core of the resulting clusters can be described as the distorted [Fe₂S₂M] square pyramid with the M atom in the apical position. The structures of the clusters were established by X-ray diffraction.     

Protonation of Cp(CO)(PPh3) RuCCPh: Formation of cationnic phenylacetylene and phenylvinylidene complexes and subsequent reaction with ethylene oxide to form the net [2 + 3] cycloadduct [Cp(CO)(PPH3)Ru=CCH(Ph)CH2CH2O]+

Protonation of the alkynyl complex Cp(CO)(PPh₃)RuCCPh (1) at low temperature affords quantitatively the vinylidened complex [Cp(CO)(PPh₃)RuCCH(Ph)]⁺ (3), which upon warming to room temperature forms an equilibrium with the η²-phenylacetylene complex [Cp(CO)(PPh₃)Ru(η²-HCCPh)]⁺ (4), with the latter predominating. Subsequent reaction with ethylene oxide yields the cyclic oxacarbene complex [Cp(CO)(PPH₃)Ru=CCH(Ph)CH₂CH₂O]⁺ (5), which can be regarded as the result of a net [3+2] cycloaddition reaction between 3 and ethylene oxide. Depronation of 5 affords teh corresponding neutral cyclic vinyl complex [Cp(CO)(PPH₃)RuC=C(Ph)CH₂CH₂O]⁺ (6), which can in turn be protonated to regenerate 5 in a diastereoselective manner. The structures of complexes 5 and 6 were determined by X-ray crystallography.     

Zur addition des thiomethyl-kations an die Wolfram-Kohlenstoff-Doppelbindung in [Cp(CO)(PMe3)WC(Tol)PR2][PF6]

Carbonyl(η⁵-cyclopentadienyl)(trimethylphosphine)[η²-(dimethylphenylphosphino-4-methylphenylcarbene]tungsten hexafluorophosphate reacts with dimethyl(methylthio)sulfonium tetrafluoroborate to yield the dicationic complexes tungstaphosphathiabicyclo[1.1.0]butane.     

First Examples of Electrophilic Addition to a Fe2Q Face of [Fe3(μ3-Q)(CO)9]2− (Q=Se, Te)—Synthesis and Characterisation of [MFe3(μ4-Q)(CO)9Cp*] and [IrFe2(μ3-Q)(CO)7Cp*] (M=Rh, Ir; Cp*=η5-C5(CH3)5)

The reaction of [Et₄N]₂[Fe₃(μ ₃-Q)(CO)₉] (Q=Se ([Et₄N]₂[1b]), Te ([Et₄N]₂[1c])) with [Cp*M(CH₃CN)₃][CF₃SO₃]₂ (M=Rh, Ir) leads to the addition of a Cp*M²⁺ unit to a Fe₂Q face of the initial cluster. In this way four new heteronuclear clusters [MFe₃(μ ₄-Q)(CO)₉Cp*] (M=Rh (2b, c); M=Ir (3b, c)) were obtained possessing a butterfly-shaped cluster core bridged by a μ ₄-Q unit. Furthermore, reaction with the Ir starting complex leads to the metal-substituted derivatives [IrFe₂(μ ₃-Q)(CO)₇Cp*] (4b, c) in lower yields, whose structures consist of a triangular metal core capped by a μ ₃-Q ligand. The products were comprehensively characterised by spectroscopic methods and the molecular structures of 2b, 3c, and 4c were established by single crystal X-ray diffraction measurements.     

Electrochemical and Photochemical Conversion of [Ru3Ir(μ 3-H)(CO)13] into [Ru3Ir(μ-H)3(CO)12]

Electrochemical and photochemical properties of the tetrahedral cluster [Ru₃Ir( ₃-H)(CO)₁₃] were studied in order to prove whether the previously established thermal conversion of this cluster into the hydrogenated derivative [Ru₃Ir(-H)₃(CO)₁₂] also occurs by means of redox or photochemical activation. Two-electron reduction of [Ru₃Ir( ₃-H)(CO)₁₃] results in the loss of CO and concomitant formation of the dianion [Ru₃Ir( ₃-H)(CO)₁₂]^2–. The latter reduction product is stable in CH₂Cl₂ at low temperatures but becomes partly protonated above 283K into the anion [Ru₃Ir(-H)₂(CO)₁₂]^– by traces of water. The dianion [Ru₃Ir( ₃-H)(CO)₁₂]^2– is also the product of the electrochemical reduction of [Ru₃Ir(-H)₃(CO)₁₂] accompanied by the loss of H₂. Stepwise deprotonation of [Ru₃Ir(-H)₃(CO)₁₂] with Et₄NOH yields [Ru₃Ir(-H)₂(CO)₁₂]^– and [Ru₃Ir( ₃-H)(CO)₁₂]^2–. Reverse protonation of the anionic clusters can be achieved, e.g., with trifluoromethylsulfonic acid. Thus, the electrochemical conversion of [Ru₃Ir( ₃-H)(CO)₁₃] into [Ru₃Ir(-H)₃(CO)₁₂] is feasible, demanding separate two-electron reduction and protonation steps. Irradiation into the visible absorption band of [Ru₃Ir( ₃-H)(CO)₁₃] in hexane does not induce any significant photochemical conversion. Irradiation of this cluster in the presence of CO with _irr>340nm, however, triggers its efficient photofragmentation into reactive unsaturated ruthenium and iridium carbonyl fragments. These fragments are either stabilised by dissolved CO or undergo reclusterification to give homonuclear clusters. Most importantly, in H₂-saturated hexane, [Ru₃Ir( ₃-H)(CO)₁₃] converts selectively into the [Ru₃Ir(-H)₃(CO)₁₂] photoproduct. This conversion is particularly efficient at _irr >340nm.     

Mixed Ruthenium–Iridium Carbonyl Cluster Complexes. Synthesis of the Anions [Ru3Ir2(CO)14]2− and [Ru3Ir2(CO)14H]− and Crystal Structures of Their [tetraphenylphosphonium]+ Salts

The reaction of Ru₃(CO)₁₂ and [Ir(CO)₄]^- (as [PPh₄]⁺ or [N(PPh₃)₂]⁺ salts) yields the anion [Ru₃Ir₂(CO)₁₄]^2- (1) which has been found to derive from the intermediate [Ru₃Ir(CO)₁₃]^- anion. Treatment of (1) with acids gives the conjugated hydrido species [Ru₃Ir₂(CO)₁₄H]^- (2). The two anions were characterized by single-crystal X-ray diffraction of their [PPh₄]⁺ salts. [PPh₄]₂[Ru₃Ir₂(CO)₁₄]: space group C2/c, Z=4, a=22.121(5) Å, b=10.546(5) Å, c=25.931(5) Å, =103.870(5)°, R=0.052 and R_w=0.130 for 3128 independent reflections with I>2(I ). [PPh₄][Ru₃Ir₂(CO)₁₄H]: space group P2₁/c, Z=8, a=22.833(5) Å, b=13.893(5) Å, c=25.810(5) Å, =92.650(5)°, R=0.070 and R_w=0.150 for 12141 independent reflections with I>2(I). Both anions 1 and 2 have a trigonal bipyramidal metal frame. There are two independent anions in the asymmetric unit of 2 differing in their ligand stereochemistry.     

Chiral or not chiral? A case study of the hexanuclear metalloprisms [Cp(6)M(6)(micro(3)-tpt-kappaN)(2)(micro-C2O4-kappaO)(3)]6+ (M = Rh, Ir, tpt = 2,4,6-tri(pyridin-4-yl)-1,3,5-triazine)

Cationic hexarhodium and hexairidium complexes with a trigonal prismatic architecture have been synthesised in good yield by self-assembly of the dinuclear oxalato-bridged complexes [Cp(2)M(2)(micro-C(2)O(4)-kappaO)Cl(2)] (M = Rh; 1: Ir; 2) with 2,4,6-tri(pyridine-4-yl)-1,3,5-triazine (tpt) in the presence of AgO(3)SCF(3). The trigonal prismatic cations [Cp(6)Rh(6)(micro(3)-tpt-kappaN)(2)(micro-C(2)O(4)-kappaO)(3)](6+) (3) and [Cp(6)Ir(6)(micro(3)-tpt-kappaN)(2)(micro-C(2)O(4)-kappaO)(3)](6+) (4) have been isolated as their triflate salts. The single-crystal X-ray structure analysis of [3][O(3)SCF(3)](6) shows two enantiomers in the racemic crystal (space group C2/c), the chirality being due to a twist of the two tpt units. By contrast, the single-crystal X-ray structure analysis of [4][O(3)SCF(3)](6) shows a perfectly eclipsed conformation of the tpt units, so that is not chiral in the crystal state (space group Fd3[combining macron]c). However, in solution, enantiodifferentiation in the presence of the chiral anion Delta-BINPHAT is observed by (1)H NMR spectrometry not only in the case of 3, but also in the case of 4. This suggests that the iridium derivative 4, which is not chiral in the solid state, adopts chiral conformations in solution.     

Reactions of [Y(BDI)(I)2(THF)] [BDI = {HC(CMeNAr)2}−, Ar = 2,6-diisopropylphenyl] with Na[M(Cp)(CO)3] (M = Cr,W): X-ray crystal structures of [{Y(BDI)[Cr(Cp)(CO)3]2(THF)}2] and [W(Cp)(CO)3][Na(THF)2]

Reaction of [Y(BDI)(I)₂(THF)] (1) with two equivalents of Na[Cr(Cp)(CO)₃] affords the dimeric complex [{Y(BDI)[Cr(Cp)(CO)₃]₂(THF)}₂] (2). Complex 2 contains two yttrium-BDI units which are each linked by two isocarbonyl bridging [Cr(Cp)(CO)₃]^? anions; a terminal, isocarbonyl bound [Cr(Cp)(CO)₃]^? anion and THF molecule completes the coordination sphere at each yttrium. This results in formation of a centrosymmetric, 12-membered C₄O₄Cr₂Y₂ ring. Forcing conditions were required to produce carbonyl metallate derivatives such as 2, as exemplified by the isolation of crystals of [W(Cp)(CO)₃][Na(THF)₂] (3) from the analogous reaction between 1 and two equivalents of Na[W(Cp)(CO)₃]. Complex 3 loses coordinated THF very easily and all isolated samples exhibit spectra consistent with the known, un-solvated form of Na[W(Cp)(CO)₃]. The crystal structure of 3 shows dimeric sodium units bridged by two THF molecules and one isocarbonyl group. Each sodium centre is further coordinated by one THF molecule and two isocarbonyl ligands. There are two crystallographically distinct [W(Cp)(CO)₃]^? units; one exhibits two bridging isocarbonyl groups and the other exhibits three bridging isocarbonyl groups to different sodium dimer units. This results in a 2-dimensional polymeric sheet network in the solid state. Complex 2 was characterised by single crystal X-ray diffraction, NMR spectroscopy, FTIR spectroscopy and CHN microanalysis; complex 3 was characterised by single crystal X-ray diffraction only.     

[Cp2Nb(CH3)2]+ [AsF6]− und [Cp2Mo(CH3)2]2+ [AsF6]2−, die ersten Niobocen- und Molybdänocendimethyl-Komplexe mit den Zentralmetallatomen in ihrer maximalen Oxidationsstufe

The preparation of the first niobium(V) and molybdenum(VI) dimethylmetallocene cations is reported. [Cp₂Nb(CH₃)₂]⁺[AsF₆]⁻ (1) and [Cp₂Mo(CH₃)₂]²⁺ [AsF₆]₂⁻ (2) (Cp = η⁵-C₅H₅) are prepared by oxidation of Cp₂Nb(CH₃)₂ and Cp₂Mo(CH₃)₂ with AsF₅ in liquid sulfur dioxide. IR investigations confirm the ionic structure of 1 and 2, and that the AsF₆⁻ is not coordinated to the metal centre.     

A study of zinc complexes of the metalloligand [Pt2(μ-S)2(PPh3)4] of the type [Pt2(μ-S)2(PPh3)4ZnL]+ (L = bidentate chelating ligand)

Reactions of [Pt₂(μ-S)₂(PPh₃)₄] with zinc acetate and an ancillary chelating ligand L (HL = 8-hydroxyquinoline, 8-tosylaminoquinoline or maltol) with added trimethylamine in methanol give new cationic platinum–zinc sulfide aggregates [Pt₂(μ-S)₂(PPh₃)₄ZnL]⁺, isolated as their BF₄^? salts. The complexes were characterized by NMR spectroscopy, ESI mass spectrometry, microelemental analysis, and an X-ray structure determination of the tosylamidoquinoline derivative [Pt₂(μ-S)₂(PPh₃)₄Zn(TAQ)]BF₄, which showed a distorted tetrahedral coordination geometry at zinc. Additional examples, containing picolinate, dithiocarbamate, or dithiophosphinate ligands were also synthesized and partly characterized in order to demonstrate a wider range of available derivatives.     

Energetics of the oxidative addition of I2 to [Ir(Μ-L)(CO)2]2 (L=S t Bu, 3,5-Me2pz,7-aza) complexes. X-ray structures of Ir(Μ-S t Bu)(I)(CO)2]2 and [Ir(Μ-3,5-Me2pz)(I)(CO)2]2

The energetics of the oxidative additive of I₂ to [Ir(-L)(CO)₂]₂ [L =t-buthylthiolate (S ^t Bu), 3,5-dimethylpyrazolate (3,5-Me₂pz), and 7-azaindolate (7-aza)] complexes was investigated by using the results of reaction-solution calorimetric measurements, X-ray structure determinations, and extended Hückel (EH) molecular orbital calculations. The addition of 1 mol of iodine to 1 mol of [Ir(-L)(CO)₂]₂, in toluene, leads to [Ir(-L)(I)(CO)₂]₂, with the formation of two Ir-I bonds and one Ir-Ir bond. The following enthalpies of reaction were obtained for this process: –125.8±4.9 kJ mol^–1 (L = S ^t Bu), –152.0±3.8 kJ mol^–1 (L=3,5-Me₂pz), and –205.9±9.9 kJ mol^⊃ (L=7-aza). These results are consistent with a possible decrease of the strain associated with the formation of three-, four-, and five-membered rings, respectively, in the corresponding products, as suggested by the results of EH calculations. The calculations also indicate a slightly stronger Ir-Ir bond for L = 3,5-Me₂pz than for L= S ^t Bu despite the fact that the Ir-Ir bond lengths are identical for both complexes. The reaction of 1 mol of [Ir(-S ^t Bu)(CO)₂]₂ with 2 mol of iodine to yield [Ir(-S ^t Bu)(I)₂(CO)₂]₂ was also studied. In this process four Ir-I bonds are formed, and from the corresponding enthalpy of reaction (–186.4±2.7 kJ mol^–1) a solution phase Ir-I mean bond dissociation enthalpy in [Ir(-S ^t Bu)(I)₂(CO)₂]₂, , was derived. This value is lower than most values reported for octahedral mononuclear Ir¹¹¹ complexes. New large-scale syntheses of the [Ir(-L)(CO)₂]₂ complexes, with yields up to 90%, using [Ir(acac)(CO)₂] as starting material, are also reported. The X-ray structures of [Ir(-L)(I)(CO)₂]₂ (L=S^tBu and 3,5-Me₂pz) complexes have been determined. For L=S^tBu the crystals are monoclinic, space group P2_l/c,a=10.741(2) å,b= 11.282(3) å,c=18.308(3) å,=96.71(1), andZ=4. Crystals of the-3,5-Me₂pz derivative are monoclinic, space group P2_l/n,a=14.002(3) å,b= 10.686(1) å,c=15.627(3) å,=112.406(8), andZ=4. In both complexes the overall structure can be described as two square-planar pyramids, one around each iridium atom, with the iodine atoms in the apical positions, and the equatorial positions occupied by two CO groups and the two sulfur atoms of the S ^t Bu ligands, or two N atoms of the pyrazolyl ligands. In the case of L=S^tBu the pyramids share a common edge defined by the two bridging sulfur atoms and for L =3,5-Me₂pz they are connected through the two N-N bonds of the pyrazolyl ligands. The complexes exhibit short Ir-Ir single bonds of 2.638(1) å for L=S^tBu and 2.637(1) å for L=3,5-Me₂Pz. The oxidative addition of iodine to [Ir(-3,5-Me₂pz)(CO)₂]₂ results in a remarkable compression of 0.608 å in the Ir-Ir separation.     

Cp2Ti(PMe3(C2H2), eine Ausgangsverbindung für Titanocen-Vinylkomplexe

Cp₂Ti(PMe₃)(C₂H₂) reacts with alcohols ROH (: R  Me, Et, Ph) and water to give new vinyltitanocene complexes.     

The reaction of [W(PMe3)4(η2-CH2PMe2)H] with carbon dioxide and dihydrogen: characterisation of [{W(PMe3)3(η1-PMe2CH2)}2(C3H2O6)] using two-dimensional nuclear magnetic resonance spectroscopy

[W(PMe₃)₄(η²-CH₂PMe₂)H] reacts with a mixture of CO₂ and H₂ (1/1, 3 atm) at room temperature to give [W(PMe₃)₄H₂(η²-O₂CO)] and [{W(PMe₃)₃(η¹-PMe₂CH₂)}₂(C₃H₂O₆)]. [{W(PMe₃)₃(η¹-PMe₂CH₂)}₂(C₃H₂O₆)] has been characterised using two-dimensional homo- and hetero-nuclear correlation NMR techniques.     

New triosmium–iridium clusters: Synthesis and molecular structure of [Os3Ir2(Cp1)2(μ-OH)(μ-CO)2(CO)8Cl] (1), [Os3IrCp1(μ-OH)(CO)10Cl] (2), [Os3IrCp1(μ-H)(μ-Cl)(η3,μ3-C5H2N(NH2)Br)(CO)9] (3) and [Os3IrCp1(μ-Cl)2(η2,μ3-C5H3N(NH)Br)(CO)7] (4)

The trinuclear osmium carbonyl cluster, [Os₃(CO)₁₀(MeCN)₂], is allowed to react with 1 equiv. of [IrCp¹Cl₂]₂ (Cp¹ = pentamethylcyclopentadiene) in refluxing dichloromethane to give two new osmium–iridium mixed-metal clusters, [Os₃Ir₂(Cp¹)₂(μ-OH)(μ-CO)₂(CO)₈Cl] (1) and [Os₃IrCp¹(μ-OH)(CO)₁₀Cl] (2), in moderate yields. In the presence of a pyridyl ligand, [C₅H₃N(NH₂)Br], however, the products isolated are different. Two osmium–iridium clusters with different coordination modes of the pyridyl ligand are afforded, [Os₃IrCp¹(μ-H)(μ-Cl)(η³,μ₃-C₅H₂N(NH₂)Br)(CO)₉] (3) and [Os₃IrCp¹(μ-Cl)₂ (η²,μ₃-C₅H₃N(NH)Br)(CO)₇] (4). All of the new compounds are characterized by conventional spectroscopic methods, and their structures are determined by single-crystal X-ray diffraction analysis.     

Synthesis and X-ray diffraction study of cs3[UO2(CH3COO)3]2[UO2(CH3COO)(NCS)2(H2O)] and Cs5[UO2(CH3COO)3]3[UO2(NCS)4(H2O)] · 2H2O

Cs₃[UO₂(CH₃COO)₃]₂[UO₂(CH₃COO)(NCS)₂(H₂O)] (I) and Cs₅[UO₂(CH₃COO)₃]₃[UO₂ (NCS)₄(H₂O)] · 2H₂O (II) have been synthesized via the reaction between uranyl acetate and cesium thiocyanate in aqueous solution. According to single-crystal X-ray diffraction data, both compounds crystallize in monoclinic system with the unit cell parameters a = 18.7036(5) Å, b = 16.7787(3) Å, c = 12.9636(3) Å, β = 92.532(1)°, space group C2/c, Z = 4, R = 0.0434 (I); and a = 21.7843(3) Å, b = 24.6436(5) Å, c = 13.1942(2) Å, β = 126.482(1)°, space group Cc, Z = 4, R = 0.0273 (II). Uranium-containing structural units of compound (I) are mononuclear [UO₂(CH₃COO)₃]^? and [UO₂(CH₃COO)(NCS)₂(H₂O)]^? moieties, which correspond to the AB ₃ ⁰¹ and AB⁰¹M ₃ ¹ crystallochemical groups (A = UO ₂ ²⁺ , B⁰¹ = CH₃COO^?, M¹ = NCS^? and H₂O). The structure of compound II is built of [UO₂(CH₃COO)₃]^? and [UO₂(NCS)₄(H₂O)]^2? complexes, which belong to the AB ₃ ⁰¹ and AM ₅ ¹ crystallochemical groups, respectively. Uranium-containing complexes in both structures are linked into a framework by hydrogen bonds and electrostatic interactions with cesium cations. The IR spectra of compounds I and II agree well with X-ray diffraction data.     

Fluorothiolate–dithioacid complexes of ruthenium(III) and osmium(III): crystal structure of [Os(SC6F5)2(S2CNEt2)(PMe2Ph)2]

Treatment of the coordinative unsaturated complexes [M(SR_F)₃(PMe₂Ph)₂] (M = Os or Ru; R_F = C₆F₅ or C₆F₄H-4) with MS₂Z (M = Na, S₂Z = S₂CNEt₂; M = K, S₂Z = S₂COEt) and [Os(SR_F)₃(PMe₂Ph)₂] (R_F = C₆F₅ or C₆F₄H-4) with MS₂Z [M = Na; S₂Z = S₂P(OEt)₂] in Me₂CO solution, gave the paramagnetic Os^III and Ru^III derivatives, [M(SR_F)₂(S₂Z)(PMe₂Ph)₂]. X-ray crystallography shows that [Os(SC₆F₅)₂(S₂CNEt₂)(PMe₂Ph)₂] has an octahedral geometry with trans-fluorothiolates, cis-phosphines and a chelating N,N-diethyldithiocarbamate ligand.