Reaktionen eines Dibismutans und von Cyclobismutanen mit Metallcarbonylen ‐ Synthesen von Komplexen mit R2Bi‐, RBi‐, Bi2‐ und Bin‐Liganden (R = Me3CCH2, Me3SiCH2)

Reactions of a Dibismuthane and of Cyclobismuthanes with Metal Carbonyls ‐ Syntheses of Complexes with R₂Bi‐, RBi‐, Bi₂‐ and Bi_n‐ligands (R = Me₃CCH₂, Me₃SiCH₂) Reactions of [Fe₂(CO)₉] with [(Me₃CCH₂)₄Bi]₂ or cyclo‐(Me₃SiCH₂Bi)_n (n = 3 ‐ 5) lead to the complexes [(R₂Bi)₂Fe(CO)₄], [RBiFe(CO)₄]₂[R = Me₃CCH₂, Me₃SiCH₂] and [Bi₂Fe₃(CO)₉]. [Bi₂{Mn(CO)₂C₅H₄CH₃}₃] forms in a photochemical reaction of [Mn(CO)₃C₅H₄CH₃] with cyclo‐(Me₃SiCH₂Bi)_n.     

Komplexchemie P-reicher Phosphane und Silylphosphane. VII. Carbonylkomplexe des Heptaphosphans(3) iPr2(Me3Si)P7

Transition Metal Complexes of P-rich Phosphanes and Silylphosphanes. VII Carbonyl Complexes of the Heptaphosphane(3) iPr₂(Me₃Si)P₇ From the reaction of iPr₂(Me₃Si)P₇ 1 with one equivalent of Cr(CO)₅THF the yellow products iPr₂(H)P₇[Cr(CO)₅] 2 and iPr₂(Me₃Si)P₇[Cr(CO)₅] 3 were isolated by column chromatography on silicagel. The P? H group in 2 results from a cleavage of the P? SiMe₃ bond during chromatography. The Cr(CO)₅ group in 2 is linked to an iPr? P^e atom, in 3 to the Me₃Si? P^e atom of the P₇ skeleton. The substituents do not force the formation of a single isomer; nevertheless 3 ist considerably favoured as compared to 2 . From the reaction of 1 with 2 equivalents of Cr(CO)₅THF the yellow iPr₂(H)P₇[Cr(CO)₅]₂ 4 was isolated bearing one Cr(CO)₅ group at an iPr? P^e atom, the other one at a P^b atom of the P₇ skeleton. Compound 3 yields with Cr(CO)₄NBD the red iPr₂(Me₃Si)P₇[Cr(CO)₅][Cr(CO)₄] 5 . Three isomers of 5 appear. Two P^e atoms of 5 are bridged by the Cr(CO)₄ group, the third P^e atom is linked to the Cr(CO)₅ ligand. iPr₂(H)P₇[Fe(CO)₄] was isolated from the reaction of 1 with Fe₂(CO)₉. ³¹P NMR and MS data are reported.     

[μ‐(Me3SiCH2Sb)5–Sb1,Sb3–{W(CO)5}2] und [{(Me3Si)2CHSb}3Fe(CO)4] – zwei cyclische Komplexe mit Antimon‐Liganden

Syntheses and Crystal Structures of [μ‐(Me₃SiCH₂Sb)₅–Sb¹,Sb³–{W(CO)₅}₂] and [{(Me₃Si)₂CHSb}₃Fe(CO)₄] – Two Cyclic Complexes with Antimony Ligands cyclo‐(Me₃SiCH₂Sb)₅ reacts with [(THF)W(CO)₅] (THF = tetrahydrofuran) to form cyclo‐[μ‐(Me₃SiCH₂Sb)₅–Sb¹,Sb³–{W(CO)₅}₂] ( 1 ). The heterocycle cyclo‐ [{(Me₃Si)₂CHSb}₃Fe(CO)₄] ( 2 ) is formed by an insertion reaction of cyclo‐[(Me₃Si)₂CHSb]₃ and [Fe₂(CO)₉]. The crystal structures of 1 and 2 are reported.     

Komplexe mit Antimon‐Liganden: [tBu2(Cl)SbW(CO)5], [tBu2(OH)SbW(CO)5], O[SbPh2W(CO)5]2, E[SbMe2W(CO)5]2 (E = Se,Te), cis‐[(Me2SbSeSbMe2)2Cr(CO)4]

Complexes Containing Antimony Ligands: [^tBu₂(Cl)SbW(CO)₅], [^tBu₂(OH)SbW(CO)₅], O[SbPh₂W(CO)₅]₂, E[SbMe₂W(CO)₅]₂ (E = Se, Te), cis‐[(Me₂SbSeSbMe₂)₂Cr(CO)₄] Syntheses of [^tBu₂(Cl)SbW(CO)₅] ( 1 ), [^tBu₂(OH)SbW(CO)₅] ( 2 ), O[SbPh₂W(CO)₅]₂ ( 3 ), Se[SbMe₂W(CO)₅]₂ ( 4 ), cis‐[(Me₂SbSeSbMe₂)₂Cr(CO)₄] ( 5 ) Te[SbMe₂W(CO)₅]₂ ( 6 ) and crystal structures of 1 – 5 are reported.     

Synthesis and Crystal Structures of the Novel Tetrameric Nitrido Complexes [{cyclo-ReN}4(S2CNEt2)6(MeOH)2(PPh3)2][BPh4]2 · CH2Cl2 · 2 H2O and [{cyclo-ReN}4(S2CNEt2)4Cl4(PMe2Ph)4] · 2 acetone

Novel tetrameric rhenium(V) complexes have been prepared from [ReNCl₂(PPh₃)₂] and [ReN(PMe₂Ph)(S₂CNEt)₂], respectively. [ReNCl₂(PPh₃)₂] reacts with 1.5 equivalents of KS₂CNEt₂ in methanol to yield the unusual dark red species [{cyclo-ReN}₄(S₂CNEt₂)₆(MeOH)₂(PPh₃)₂][BPh₄]₂ · CH₂Cl₂ · 2 H₂O ( 1 ). The crystal structure of the tetramer (triclinic, space group P1, a = 13.842(2), b = 15.213(2), c = 16.796(3) Å, α = 67.88(1), β = 70.90(1), γ = 88.05(1)°, U = 3080.2(8) ų, Z = 1) shows four rhenium atoms in a square configuration which are bridged via linear asymmetric Re≡N–Re groups with bond lengths of about 169 and 203 pm. The molecule contains a centre of symmetry with two distinct octahedral rhenium environments. The first rhenium environment contains two bidentate dithiocarbamate ligands which complete the octahedral geometry and the second contains a bidentate dithiocarbamate ligand, coordinated methanol and has retained a single phosphine coligand. A symmetric compound containing the {cyclo-ReN}₄ core is obtained from the reaction of [ReN(PMe₂Ph)(S₂CNEt₂)₂] with Al₂Cl₆ in acetone. [{cyclo-ReN}₄(S₂CNEt₂)₄Cl₄(PMe₂Ph)₄] · 2 acetone ( 2 ) forms red crystals (monoclinic, space group C2/c, a = 21.432(6), b = 13.700(3), c = 28.060(9) Å, β = 102.37(1)°, U = 8048(4) Å3, Z = 4) with each rhenium atom coordinated by a bidentate dithiocarbamato, a phosphine and a chloro ligand. The non-planar 8-membered {ReN}₄ ring contains asymmetric Re≡N–Re bridges (mean values: 1.69 Å and 2.029 Å, respectively). In contrast, reaction of [ReNCl(S₂CNEt₂)(PMe₂Ph)₂] with one equivalent of K[S₂CN(Me)CH₂CH₂NMe₃]I gave the mixed dithiocarbamato-cation [ReN(S₂CNEt₂)(S₂CN(Me)CH₂CH₂NMe₃)(PMe₂Ph)]⁺ ( 3 ) which was isolated as a tetraphenylborate salt.     

Reaktionen von Cyclostibanen (RSb)n [R = (Me3Si)2CH,n = 3; Me3CCH2, n = 4, 5] mit den Übergangsmetallcarbonyl‐Komplexen [W(CO)5(thf)], [CpxMn(CO)2(thf)], [CpxCr(CO)3]2 und [Co2(CO)8]; Cpx = MeC5H4

Reactions of Cyclostibanes, (RSb)_n [R = (Me₃Si)₂CH, n = 3; Me₃CCH₂, n = 4, 5] with the Transition Metal Carbonyl Complexes [W(CO)₅(thf)], [Cp^xMn(CO)₂(thf)], [Cp^xCr(CO)₃]₂, and [Co₂(CO)₈]; Cp^x = MeC₅H₄ (RSb)₃ [R = (Me₃Si)₂CH] reacts with [W(CO)₅(thf)], [Cp^xMn(CO)₂(thf)], or [Co₂(CO)₈] to give [(RSb)₃W(CO)₅] ( 1 ), [RSb{Mn(CO)₂Cp^x}₂] ( 2 ) or [RSbCo(CO)₃]₂ ( 3 ). The reaction of (R′Sb)_n (n = 4, 5; R′ = Me₃CCH₂) with [Cp^xCr(CO)₃]₂ leads to [(R′Sb)₄{Cr(CO)₂Cp^x}₂] ( 4 ); Cp^x = MeC₅H₄, thf = Tetrahydrofuran.     

Über das Tri(phosphorano)borazinium-Monokation [H3B3(NPEt3)3Cl2]+. Kristallstrukturen von Me3SiNPR3 · BH3 (R = Et,Ph), [H3B3(NPEt3)3Cl1,85Br0,15]Br · CCl4 und des Hydrolyseproduktes NH4[B5O6(OH)4] · 2 H2O

On the Tri(phosphorano)borazinium Monocation [H₃B₃(NPEt₃)₃Cl₂]⁺. Crystal Structures of Me₃SiNPR₃ · BH₃ (R = Et, Ph), [H₃B₃(NPEt₃)₃Cl_1.85Br_0.15]Br · CCl₄, and of the Product of Hydrolysis NH₄[B₅O₆(OH)₄] · 2 H₂O The crystal structures of the donor-acceptor complexes of the silylated phosphanimines with borane which are suitable as educts for the synthesis of tri(phosphorano)borazinium ions, Me₃SiNPR₃ · BH₃ (R = Et, Ph), are described. After addition of CCl₄ the reaction of Me₃SiNPEt₃ with HBBr₂ · SMe₂ in CH₂Cl₂ leads to the tri(phosphorano)borazinium monocation [H₃B₃(NPEt₃)₃Cl₂]⁺, which is characterized crystallographically as [H₃B₃ · (NPEt₃)₃Cl_1.85Br_0.15]Br · CCl₄. It complements the series of the tri(phosphorano) cations [H₃B₃(NPEt₃)₃]³⁺ and [H₄B₃(NPEt₃)₃]²⁺ by the monocation. NH₄[B₅O₆(OH)₄] · 2 H₂O can be isolated as product of hydrolysis of the tri(phosphorano)borazinium ions; its crystal structure is redetermined, because in the literature it is based on a wrong space group. Me₃SiNPEt₃ · BH₃ ( 1 ): Space group P1, Z = 4, lattice dimensions at 213 K: a = 710.9(4), b = 1465.9(3), c = 1536.0(3) pm, α = 107.05°, β = 99.40(3)°, γ = 97.41(3)°; R = 0.0740. Me₃SiNPPh₃ · BH₃ ( 2 ): Space group P2₁/c, Z = 4, lattice dimensions at 203 K: a = 934.6(1), b = 1398.6(1), c = 1626.1(1) pm, β = 103.52(1)°; R = 0.0556. [H₃B₃(NPEt₃)₃Cl_1.85Br_0.15]Br · CCl₄ ( 3 ): Space group P2₁/n, Z = 4, lattice dimensions at 223 K: a = 1237.9(3), b = 1214.1(3), c = 2402.4(4) pm, β = 93.52(1)°. 3 holds a B₃N₃ six-membered ring in a distorted boat conformation. NH₄[B₅O₆(OH)₄] · 2 H₂O ( 4 ): Space group Aba2, Z = 4, lattice dimensions at 273 K: a = 1131.3(1), b = 1103.0(1), c = 923.0(1) pm; R = 0.0564.     

ORGANOBISMUTH HOMOCYCLES (RBi)n AND HETEROCYCLES (RBiS)2

The homocycles (RBi)_n (n = 3–5) react with MeC₅ H₄Mn(CO)₂(thf) (thf = tetrahydrofuran) or Fe₂(CO)₉ to give Bi₂[Mn(CO)₂MeC₅ H₄]₃ (1) or Bi₂Fe₃(CO)₉ (3). Reaction of R₄Bi₂ (R = Me₃SiCH₂) with Fe₂(CO)₉ in toluene gives R₂Bi₂Fe₂(CO)₈ (4) and R₄Bi₂Fe(CO)₄ (5). The heterocycles (RBiS)₂(R = 2-(Me₂NCH₂)C₆ H₄ (6), 2, 6-(Me₂NCH₂)₂ C₆ H₄ (7) are formed by reaction of the corresponding dihalides RBiCl₂ with Na₂S. The reaction of (RBiS)₂(R = 2-(Me₂NCH₂)C₆ H₄) with W(CO)₅(thf) leads to (RBiS)₂[W(CO)₅]₂ (8).     

Über die komplexen Hydroxide des Chroms: Na9[Cr(OH)6]2(OH)3 · 6 H2O und Na4[Cr(OH)6]X · H2O (X = Cl, (S2)1/2) – Synthese,Kristallstruktur und thermisches Verhalten

Complex Hydroxides of Chromium: Na₉[Cr(OH)₆]₂(OH)₃ · 6 H₂O and Na₄[Cr(OH)₆]X · H₂O (X = Cl, (S₂)_1/2) – Synthesis, Crystal Structure, and Thermal Behaviour Green plate‐like crystals of Na₉[Cr(OH)₆]₂(OH)₃ · 6 H₂O (triclinic, P1, a = 872.9(1) pm, b = 1142.0(1) pm, c = 1166.0(1) pm, α = 74.27(1)°, β = 87.54(1)°, γ = 70.69(1)°) are obtained upon slow cooling of a hot saturated solution of Cr^III in conc. NaOH (50 wt%) at room temperature. In the presence of chloride or disulfide the reaction yields green prismatic crystals of Na₄[Cr(OH)₆]Cl · H₂O (monoclinic, C2/c, a = 1138.8(2) pm, b = 1360.4(1) pm, c = 583.20(7) pm, β = 105.9(1)°) or green elongated plates of Na₄[Cr(OH)₆](S₂)_1/2 · H₂O (monoclinic, P2₁/c, a = 580.8(1) pm, b = 1366.5(3) pm, c = 1115.0(2) pm, β = 103.71(2)°), respectively. The latter compounds crystallize in related structures. All compounds can be described as distorted cubic closest packings of the anions and the crystal water molecules with the cations occupying octahedral sites in an ordered way. The thermal decomposition of the compounds was investigated by DSC/TG or DTA/TG and high temperature X‐ray powder diffraction measurements. In all cases the final decomposition product is NaCrO₂.     

Komplexchemie at P-reicher Phosphane und Silylphosphane. VI. Bildung und Struktur der Chromcarbonylkomplexe des Tris(trimethylsilyl) heptaphosphanortricyclans (Me3Si)3P7

Formation and Structures of Chromium Carbonyl Complexes of Tris(trimethylsily)heptanortricyclane (Me₃Si)₃P₇ (Me₃Si)₃P₇ 1 reacts with one equivalent of Cr(Co)₅THF 2 to give the yellow (Me₃Si)₃P₇[Cr(Co)₅] 4. The Cr(Co)₅group is attached to a P^e atom. Yellow (Me₃Si)₃P₇[Cr(CO)₅]₂ 5 is obtained either from reacting 1 with two equivalents of 2 , or from 4 with one equivalent of 2. One Cr(CO)₅ groups in 5 is coordinated to a P^e atom, the other one to a P,^b atom. Similarly, Yellow (Me₃Si)₃P₇[Cr(CO)₅]₃ 6 results from reacting 5 with one equivalent of 2 . Two Cr(CO)₅ groups in 6 are linked to P^b atoms, and the third one either to a P^e or the P^a atom (assignment not completely clear). Derivatives containing a P^e bridge appear in reactions of 1 with higher amounts of 2 . Such, 5 forms mixtures of the red compounds (Me₃Si)₃P₇ × [Cr(CO)₅]₂[Cr(CO)₄] 8 and (Me₃Si)₃P₇[Cr(CO)₅] × [Cr(CO)₄] 9 , and even preferably 9 with four equivalents of 2 . In 8 , one Cr(CO)₅ group is attached to that p^e atom which is not engaged in the Cr(CO)₄ bridge, and the second to one of the P^b atoms directly adjacent to the bridge. The additional Cr(CO)₅ group in 9 is coordinated to the remaining P^b atom directly adjacent to the bridge. In reactions of 5 with even higher amounts of 2 , four Cr(CO)₅ groups and one Cr(CO)₄ bridge attach to the basic P₇ skeleton to from the less stable Me₃P₇[Cr(CO)₅]₄[Cr(CO)₄]. (Me₃Si)₃P₇ 1 reacts considerably slower with Cr(CO)₅THF 2 than R₃P₇ (R = Et, iPr). Cr(CO)₄NBD 3 reacts with 1 , but it was not possible to isolate (Me₃Si)₃P₇[Cr(CO)₄]. However, 4 with 3 forms (Me₃Si)₃P₇[Cr(CO)₅][Cr(CO)₄] 7 , and 5 with 3 yields (Me₃Si)₃P₇[Cr(CO)₅]₂[Cr(CO)₄] 8 . The structures of 4 , 5 , 7 , 8 or 9 are quite analogous to those of the derivatives of Et₃P₇ but there exist significant differences in stability and reactivity. While Et₃P₇[Cr(CO)₅]₂ in solution rearranges to give the stable Et₃P₇[Cr(CO)₅][Cr(CO)₄], the analogous (Me₃Si)₃P₇[Cr(CO)₅][Cr(CO)₄] 7 is not stable and is not obtained from (Me₃Si)₃P₇[Cr(CO)₅]₂ 5 . Et₃P₇[Cr(CO)5]₃ can just be detected spectroscopically and rearranges easily to give Et₃P₇[Cr(CO)₅]₂ [Cr(CO)₄] whereas (Me₃Si)₃P₇[Cr(CO)₅]₃ 6 can be isolated. These differences are caused by the greater steric requirements of Me₃Si groups. The formation of a P^e–Cr(CO)₄–P^e bridge, e.g., requires a Me₃Si group in 1 to switch from the s to the as position. Whereas many of the complex compounds of R₃P₇ (R = Et, iPr) crystallize easily, the analogous derivatives of (Me₃Si)₃P₇ did not yield crystals. The structures of the products were assigned by evaluating the coordination shift in their ₃₁P NMR spectra and by comparision of these spectra with those of such derivatives of Et₃P₇ which previously had been investigated by single crystal structure determinations.     

Darstellung,Strukturen und Eigenschaften von Tris-hexamethyl-trisila-tetraphospha-nortricyclen-bis-chromtricarbonyl [P4(Sime2)3]3[Cr(CO)3]2

Preparation, Structures, and Properties of Tris-hexamethyl-trisila-tetraphospha-nortricyclene-bis-chromiumtricarbonyl [P₄(Sime₂)₃]₃[Cr(CO)₃]₂ Hexamethyl-trisila-tetraphospha-nortricyclene P₄(Sime₂)₃ 1 reacts with C₆H₆Cr(CO)₃ or (CHT)Cr(CO)₃ (CHT ? Cycloheptatriene) under formation of [P₄(Sime₂)₃]₃[Cr(CO)₃]₂ 3 (red crystals), in which each of the Cr atoms is attached to one P atom of a P₃ ring of the three molecules 1 . 3 can also be prepared by heating a solution of P₄(Sime₂)₃Cr(CO)₅ in benzene or THF up to 120–1307deg;C. The compound 3 crystallizes in an orthorhombic and a hexagonal form, the latter being stabilized by one mole toluene. As revealed by single crystal investigations, the symmetry ¯6, distances and angles are nearly unchanged. The o-form corresponds to a face centered cubic packing of the molecules, whereas the h-form is hexagonal close packed.     

Darstellung,Kristallstrukturen und Schwingungsspektren von trans‐[Pt(N3)4(ECN)2]2–, E = S,Se

Synthesis, Crystal Structures, and Vibrational Spectra of trans ‐[Pt(N₃)₄(ECN)₂]^2–, E = S, Se By oxidative addition to (n‐Bu₄N)₂[Pt(N₃)₄] with dirhodane in dichloromethane trans‐(n‐Bu₄N)₂[Pt(N₃)₄(SCN)₂] and by ligand exchange of trans(n‐Bu₄N)₂[Pt(N₃)₄I₂] with Pb(SeCN)₂ trans‐(n‐Bu₄N)₂[Pt(N₃)₄(SeCN)₂] are formed. X‐ray structure determinations on single crystals of trans‐(Ph₄P)₂[Pt(N₃)₄(SCN)₂] (triclinic, space group P 1, a = 10.309(3), b = 11.228(2), c = 11.967(2) Å, α = 87.267(13), β = 75.809(16), γ = 65.312(17)°, Z = 1) and trans‐(Ph₄P)₂[Pt(N₃)₄(SeCN)₂] (triclinic, space group P 1, a = 9.1620(10), b = 10.8520(10), c = 12.455(2) Å, α = 90.817(10), β = 102.172(10), γ = 92.994(9)°, Z = 1) reveal, that the compounds crystallize isotypically with octahedral centrosymmetric complex anions. The bond lengths are Pt–S = 2.337, Pt–Se = 2.490 and Pt–N = 2.083 (S), 2.053 Å (Se). The approximate linear Azidoligands with N^α–N^β–N^γ‐angles = 172,1–175,0° are bonded with Pt–N^α–N^β‐angles = 116,7–120,5°. In the vibrational spectra the platinum chalcogen stretching vibrations of trans‐(n‐Bu₄N)₂[Pt(N₃)₄(ECN)₂] are observed at 296 (E = S) and in the range of 186–203 cm^–1 (Se). The platinum azide stretching modes of the complex salts are in the range of 402–425 cm^–1. Based on the molecular parameters of the X‐ray determinations the IR and Raman spectra are assigned by normal coordinate analysis. The valence force constants are f_d(PtS) = 1.64, f_d(PtSe) = 1.36, f_d(PtN^α) = 2.33 (S), 2.40 (Se) and f_d(N^αN^β, N^βN^γ) = 12.43 (S), 12.40 mdyn/Å (Se).     

Protonation and Hydrogen Atom Abstraction Reactions in the Synthesis of the [HP7M(CO)3]2– Ions (M = Cr,W)

Ethylenediamine (en) solutions of [P₇M(CO)₃]^3– (M = Cr, W) react with weak acids to give [HP₇M(CO)₃]^2– ions where M = Cr ( 4 a ) and W ( 4 b ) in high yields. Competition studies with known acids revealed a pK_a range for 4 b in DMSO of 17.9 to 22.6. The [P₇M(CO)₃]^3– complexes also react with one-half equivalent of I₂ to give 4 through an oxidation/hydrogen atom abstraction process. Labeling studies show that the abstracted hydrogen originates from the [K(2,2,2-crypt)]⁺ ions or from the solvent (DMSO-d₆) in the absence of [K(2,2,2-crypt)]⁺ or other good hydrogen atom donors. In the solid state, the ions have no crystallographic symmetry but in solution they show virtual C_s symmetry (³¹P NMR spectroscopy) due to an intramolecular wagging process. Crystallographic data for [K(2,2,2-crypt)]₂[HP₇W(CO)₃]: triclinic, P 1, a = 10.9709(8) Å, b = 13.9116(10) Å, c = 19.6400(14) Å, α = 92.435(6)°, β = 93.856(6)°, γ = 108.413(6)°, V = 2831.2(4) ų, Z = 2, R(F) = 7.65%, R(wF²) = 14.17% for all 7400 reflections. For [K(2,2,2-crypt)]₂[HP₇Cr(CO)₃]: triclinic, P 1, a = 12.000(3) Å, b = 14.795(3) Å, c = 17.421(4) Å, α = 93.01(2)°, β = 93.79(2)°, γ = 110.72(2)°, V = 2877(2) ų, Z = 2.     

Darstellung und spektroskopische Untersuchungen von M(CO)4L2- und M(CO)3L3-Komplexen (M = Cr,Mo, W; L = Me3SiOCH2PMe2, Me2(CH2CH) SiOCH2PMe2)

Preparation and spectroscopical Investigations of M(CO)₄L₂ and M(CO)₃L₃ Complexes (M = Cr, Mo, W; L = Me₃SiOCH₂PMe₂, Me₂(CH₂?CH)SiOCH₂PMe₂ The coordinating properties of the ligands L¹ (?Me₃SiOCH₂PMe₂) and L² (?Me₂ViSiOCH₂PMe₂)¹) have been studied by synthesis and spectroscopic investigations (IR, NMR, MS) of their complexes M(CO)₄L₂ and M(CO)₃L₃(M = Cr, Mo, W). The complexes are obtained by replacement of norbornadiene (NBD) in M(CO)₄NBD or cycloheptatriene CHT in M(CO)₃CHT. Spectroscopic data (v(CO), δ δ) support the σ-donor/-π-acceptor model of the MP bonds.     

Bildung und Struktur des [{cyclo‐P4(PtBu2)4}{Ni(CO)2}2]

Coordination Chemistry of P‐rich Phosphanes and Silylphosphanes. XXVI. Formation and Structure of [{ cyclo ‐P₄(P^tBu₂)₄}{Ni(CO)₂}₂] [{cyclo‐P₄(P^tBu₂)₄}{Ni(CO)₂}₂] is formed by reaction of the cyclotetraphosphane P₄(P^tBu₂)₄ with [Ni(CO)₄]. Each Ni(CO)₂ unit is coordinated by two adjacent ^tBu₂P groups forming two five‐membered P₄Ni rings above and below the planar cyclotetraphosphane ring, respectively. The compound crystallizes in the triclinic space group P 1 (No. 2) with a = 893.29(5), b = 1140.75(7), c = 1235.52(8) pm, α = 109.179(7), β = 100.066(7), γ = 97.595(7)° and Z = 1.     

Kristallstrukturen,spektroskopische Charakterisierung und Normalkoordinatenanalyse von (n‐Bu4N)2[M(ECN)4] (M = Pd,Pt; E = S,Se)

Crystal Structures, Spectroscopic Analysis, and Normal Coordinate Analysis of ( n ‐Bu₄N)₂[M(ECN)₄] (M = Pd, Pt; E = S, Se) The reaction of (NH₄)₂[PdCl₄] or K₂[PtCl₄] with KSCN or KSeCN in aqueous solutions yields the complex anions [Pd(SCN)₄]^2–, [Pt(SCN)₄]^2– and [Pt(SeCN)₄]^2–, which are converted into (n‐Bu₄N) salts with (n‐Bu₄N)HSO₄. (n‐Bu₄N)₂[Pd(SeCN)₄] is formed by treatment of (n‐Bu₄N)₂[PdCl₄] with (n‐Bu₄N)SeCN in acetone. X‐ray structure determinations on single crystals of (n‐Bu₄N)₂[Pd(SCN)₄] (monoclinic, space group P2₁/n, a = 13.088(3), b = 12.481(2), c = 13.574(3) Å, β = 91.494(15)°, Z = 2), (n‐Bu₄N)₂[Pd(SeCN)₄] (monoclinic, space group P2₁/n, a = 13.171(2), b = 12.644(2), c = 13.560(2) Å, β = 91.430(11)°, Z = 2) and (n‐Bu₄N)₂[Pt(SeCN)₄] (monoclinic, space group P2₁/n, a = 13.167(2), b = 12.641(1), c = 13.563(2) Å, β = 91.516(18)°, Z = 2) reveal, that the compounds crystallize isotypically and the complex anions are centrosymmetric and approximate planar. In the Raman spectra the metal ligand stretching modes of (n‐Bu₄N)₂[Pd(SCN)₄] ( 1 ) and (n‐Bu₄N)₂[Pt(SCN)₄] ( 3 ) are observed in the range of 260–303 cm^–1 and of (n‐Bu₄N)₂[Pd(SeCN)₄] ( 2 ) and (n‐Bu₄N)₂[Pt(SeCN)₄] ( 4 ) in the range of 171–195 cm^–1. The IR and Raman spectra are assigned by normal coordinate analysis using the molecular parameters of the X‐ray determination. The valence force constants are f_d(PdS) = 1.17, f_d(PdSe) = 1.17, f_d(PtS) = 1.44 and f_d(PtSe) = 1.42 mdyn/Å. The ⁷⁷Se NMR resonances are 23 for 2 , –3 for 4 and the ¹⁹⁵Pt NMR resonances 549 for 3 and 130 ppm for 4 .     

Perfluormethyl-Element-Liganden. XVIII. Darstellung und spektroskopische Untersuchung von M(CO)5L und M(CO)4L2-Komplexen [L = MenP(CF3)3−n; n = 0–3; M = Cr,Mo, W]

Perfluoromethyl-Element-Ligands. XVIII. Preparation and Spectroscopic Investigation of M(CO)₅L and M(CO)₄L₂ Complexes [L = Me_nP(CF₃)_3?n; n = 0–3; M = Cr, Mo, W] M(CO)₅L and cis-M(CO)₄L₂ complexes, respectively [M = Cr, Mo, W; L = Me_nP(CF₃)_3?n; n = 0–3] are prepared reacting M(CO)₅ · THF or M(CO)₄norbor with L at room temperature. The cis-compounds isomerize above 50°C yielding the trans-complexes; the rate of isomerization increases with increasing number of CF₃ groups. Thermal reaction of M(CO)₆ (M = Cr, Mo, W) with P(CF₃)₃ yields M(CO)₅P(CF₃)₃ and trans-M(CO)₄[P(CF₃)₃]₂. Introduction of three P(CF₃)₃ ligands by reaction with M(CO)₃(cycloheptatriene) (M = Cr, Mo) proves unsuccessful; besides little M(CO)₅P(CF₃)₃ trans-M(CO)₄[P(CF₃)₃]₂ is formed. The new compounds are characterized by analytical and spectroscopic (n.m.r., i.r., MS) methods.     

Untersuchungen zur Darstellung von [CpxSb{M(CO)5}2] (Cpx = Cp,Cp*; M = Cr,W)

Investigations of the Synthesis of [Cp^xSb{M(CO)₅}₂] (Cp^x = Cp, Cp*; M = Cr, W) The reaction of CpSbCl₂ with [Na₂{Cr₂(CO)₁₀}] leads to the chlorostibinidene complex [ClSb{Cr(CO)₅}₂(thf)] ( 1 ), whereas the reaction of CpSbCl₂ with [Na₂{W₂(CO)₁₀}] results in the formation of the complexes [ClSb{W(CO)₅}₃] ( 2 ), [Na(thf)][Cl₂Sb{W(CO)₅}₂] ( 3 ), [ClSb{W(CO)₅}₂(thf)] ( 4 ) and [Sb₂{W(CO)₅}₃] ( 5 ). The stibinidene complex [CpSb{Cr(CO)₅}₂] ( 6 ) is obtained by the reaction of [ClSb{Cr(CO)₅}₂] with NaCp, while its Cp* analogue [Cp*Sb{Cr(CO)₅}₂] ( 7 ) is formed via the metathesis of Cp*SbCl₂ with [Na₂{Cr₂(CO)₁₀}]. The products 2 , 3 , 4 and 7 are additionally characterised by X‐ray structure analyses.     

Syntheses and Characterization of Manganese-Tellurolate Complexes by Using Chelating Metalloligand cis-[Mn(Co)4(TePh)2]− and Potential Electrophilic TeMe+ Reagent

The cis-[Mn(CO)₄(TePh)₂]^?, similar to bidentate ligand PhTe(CH₂)₃TePh, acts as a “chelating metalloligand” for the synthesis of metallic tellurolate compounds. The reaction of cis[Mn(CO)₄(TePh)₂]^? with BrMn(CO)₅ in THF leads to a mixture of products[(CO)₃,BrMn(μ-TePh)₂Mn(CO)₄]^? (1) and Mn₂(μ-TePh)₂(CO)_g (2). Complex 1 crystallizes in the triclinic space group Pl? with a = 11.309(3) Å, b = 14.780(5) Å, c = 19.212(6) Å, a = 76.05(3)° β = 72.31(3)°, γ = 70.41(3)° V = 2848(2) Å₃, Z = 2. Final R = 0.034 and R_w = 0.035 resulting from refinement of 10021 total reflections with 677 parameters, Dropwise addition of (MeTe)₂ to a solution of [Me₃O][BF₄] in CH₃CN leads to formation of [Me₂TeTeMe][BF₄], a potential MeTe⁺ donor ligand. In contrast to oxidative addition of diphenyl ditelluride to [Mn(CO)s]^? to give cis-[Mn(CO)₄(TePh)₂]^? which was thermally transformed into [(CO)₃Mn(μ-TePh)₃Mn(CO)₃]^?, reaction of [Mn(CO)₅]^?with [Me₂TeTeMe]⁺ proceeded to give the monomeric species MeTeMn(CO)₅ as initial product which was then dimerized into Mn₂(μ-TeMe)₂(CO)_g (4).     

Über die Reaktionen von CH2=P(NMe2)3 mit Fe(CO)5, Cr(CO)6 und CS2; Molekülstrukturen von [MeP(NMe2)3][(CO)5CrC(O)CH=P(NMe2)3] und (CO)4Fe=C(OMe)CH=P(NMe2)3

The Reactions of CH₂=P(NMe₂)₃ with Fe(CO)₅, Cr(CO)₆, and CS₂; Molecular Structures of [MeP(NMe₂)₃][(CO)₅CrC(O)CH=P(NMe₂)₃], and (CO)₄Fe=C(OMe)CH=P(NMe₂)₃ The ylide CH₂=P(NMe₂)₃ ( 1 ) reacts with several binary transition metal carbonyls M(CO)_x to produce the corresponding salt like compounds [MeP(NMe₂)₃][(CO)_x–1MC(O)CH=P(NMe₂)₃] (M = Fe ( 3 ), Cr ( 4 )). The related reaction with CS₂ leads to the salt [MeP(NMe₂)₃][SC(S)CH=P(NMe₂)₃] ( 2 ). While 4 is thermally stable, 3 rapidly decomposes at room temperature with formation of [MeP(NMe₂)₃]₂[Fe₂(CO)₈] ( 8 ). Alkylation of 3 (at –50 °C) and 4 with MeSO₃CF₃ produces the related carbene complexes (CO)_x–1M=C(OMe)CH=P(NMe₂)₃ ( 5 ) and ( 6 ); the reaction of 3 with Me₃SiCl results in the formation of the carbene complex (CO)₄Fe=C(OSiMe₃)CH=P(NMe₂)₃ ( 7 ). 4 crystallizes in the space group P2₁2₁2₁ (No. 19) with a = 1111.1(2), b = 1476.1(3), c = 1823.1(4) pm and Z = 4. 5 crystallizes in the space group P2₁/n (No. 14) with a = 1303.6(3), b = 910.5(4), c = 1627.0(4) pm, β = 96.06(2)° and Z = 4. The compounds have been characterized by elemental analyses, NMR (¹H, ¹³C, ³¹P) and IR spectroscopy.