Concerning the silicon-germanium bond: mass spectral fragmentations of isomeric SiGe compounds R3EE′R3 (E  Si,E′  Ge,R  Ph,Me,(η5-C5H4)Fe (C5H5), (η5-C5H5)Fe(CO)2 and (η5-C9H7) Fe(CO)2)

Isomeric pairs of silicon-germanium compounds containing a SiGe bond (Me₃SiGePh₃ (I) and Ph₃SiGeMe₃ (II); FpSiMe₂GeMe₃ (III) and FpGeMe₂SiMe₃ (IV) (Fp = (η⁵-C₅H₅)Fe(CO)₂); IFpSiMe₂GeMe₃ (V) and IFpGeMe₂SiMe₃ (VI) (IFp = (η⁵-C₉H₇)Fe(CO)₂); IFpSiMe₂GePh₃ (VII) and IFpGeMe₂SiPh₃ (VIII) and the complex FcSiMe₂GeMe₂Fc (IX) (Fc = ferrocenyl) have been synthesized and examined by mass spectrometry.The R₃SiGeR′₃ compounds I and II exhibit considerable exchange of R groups to produce [R_3-nR′_nSi]⁺ and [R′_3-nR_nGe]⁺ ion in progressively lesser amounts as n = 1 → 2 → 3. For the metal-substituted complexes containing the grouping FeSiGe fragmentation occurs predominantly via SiGe bond cleavage with formation of ions containing the silylene ligand [FeSiR₂]⁺. Complexes with the FeGeSi backbone undergo preferential scission of the FeGe bond, illustrating the general bond strength trend FeSi > SiGe. Upon direct cleavage of the SiGe bond in R₃SiGeR₃ compounds, the percentage of the charge carried by [R₃Si]⁺ ions significantly exceeds that carried by [R₃Ge]⁺ ions, reflecting the greater electronegativity of Ge polarizing the SiGe bond.     

Synthese und Reaktivität von Silicium-übergangsmetall-Komplexen: XXI. Ferrio-azidosilane and Ferriosilyl-iminophosphorane

Reaction of the ferriochlorosilanes R₅C₅(CO)₂FeSiR′_3-nCl_n (1a–1f) with sodium azide in tetrahydrofuran yields the ferrio- (mono-, bis-, and tris-azido)silanes R₅C₅(CO)₂FeSiR′_3-n(N₃)_n (R = H, Me; R′ = Me, H; n = 1–3) (2a–2f). CCl₄ converts Cp(CO)₂FeSiMe(H)N₃ (2a) into the ferrioazido(chloro)silane Cp(CO)₂-FeSiMe(Cl)N₃ (3). Treatment of 2d, 2f with Me₃P results in the formation of the ferriosilyl-iminophosphoranes Cp(CO)₂FeSi(N₃)(R)NPMe₃ (R = Me, N₃), (4a, 4b) by N₂ elimination.     

Methylidyne tricobalt nonacarbonyl clusters; optically active silicon and germanium derivatives,and substitutions at silicon

The preparation and alcoholysis of chiral chlorosilanes containing the nonacarbonyltricobaltcarbon cluster, RR′Si(Cl)CCo₃(CO)₉, is described. The alkoxy derivatives react with i-Bu₂AlH or BF₃ · Et₂O to give the corresponding silicon hydride or fluoride. Reaction of methylidynetricobalt nonacarbonyl with optically active silanes of germane gave the optically active cluster complexes R¹R²R³M^*CCo₃(CO)₉ (M^* = Si, Ge). These compounds react with phosphine to give the monosubstituted R¹R²R³M^*CCo₃(CO)₈(PR₃ (M^* = Si, Ge). The diastereomers have been resolved in the case of the MePhSi (Obornyl) CCo₃(CO)₉ complex.     

IR- und NMR-spektroskopische Untersuchungen zu Substituenteneffekten in Siloxy- und Alkoxysilanen

I.R. and N.M.R. Spectroscopic Investigations on Substituent Effects in Siloxy and Alkoxysilanes Siloxy and alkoxysilanes of the types (RMe₂SiO)₃SiH, (RMe₂CO)₃SiH, (Me_3–nPh_nSiO)_m(Me₃SiO)_3–mSiH (m = 1—3, n = 1—3), and Me_3–n(RMe₂SiO)_nSiH (n = 1—3) have been prepared. The influence of the substituent effects through the (Me₂)Si? O- a (Me₂)C? O- group on the Si? H band is approximately equal.     

Reactions of tetracarbonylcobaltate(-I) with chlorosilanes in ether solvents

The reactions of NaCo(CO)₄ with Me_nSiCl_4?n (n = 0–3) in diethylether (Et₂O) and in tetrahydrofuran (THF) have been studied. Three distinct reaction pathways were recognised which depend on the acidity of the chlorosilane and basicity of solvent. Attack at the silicon centre via the Co atom of Co(CO)₄^? leads to formation of a SiCo bond; reaction involving a CO ligand of Co(CO)₄^? gives clusters R₃SiOCCo₃(CO)₉; and chlorosilane induced attack of Co(CO)₄^? on the solvent gives products derived from THF molecules.     

Spektroskopische Untersuchungen zu Substituenteneffekten in Silylmethylsilanen

Spectroscopic Investigations on Substituent Effects in Silylmethylsilanes The silanes Me_3?n(Me₃SiCH₂)_nSiH (n = 1–3), (RMe₂SiCH₂)₃SiH (R = n-Bu, n-Pr, Et, PhCH₂, Ph) and Me₃ElCH₂SiMe₂H (El = Ge, Sn) were prepared. The frequencies of the Si? H stretching vibration, the ²⁹Si? ¹H coupling constants and the ²⁹Si n.m.r. chemical shifts were measured. The ?(SiH) and J(²⁹Si? ¹H) values in the silanes Me_3?n(Me₃SiCH₂)_nSiH depend on the number of trimethylsilymethyl groups. There is hardly an influence of the substituents R on these values in the silanes (RMe₂SiCH₂)₃SiH. The frequencies of the Si? H stretching vibrations in the silanes Me₃ElCH₂SiMe₂H (El = Si, Ge, Sn) show the order Si?Ge > Sn. The ₂₉Si n.m.r. chemical shifts of the Si(H) signals are approximately equal in the silanes Me_3?n(Me₃SiCH₂)_nSiH and (RMe₂SiCH₂)₃SiH.     

Hydrido-silyl-komplexe: VII. Strukturchemische und 29Si-NMR-spektroskopische untersuchungen an C5R′5(CO)(L)Mn(H)SiR3. Einfluss der substituenten R und R′ sowie des liganden L auf die Mn,H,Si-dreizentrenbindung

In C₅R′₅(CO)(L)Mn(H)SiR₃ complexes the oxidative addition reaction of the silane HSiR₃ with the C₅R′₅(CO)(L)Mn fragment (L = CO, PR₃, P(OR)₃, CNR) is incomplete. These compounds contain Mn,H,Si two-electron three-center bonds in their ground states, which are strongly influenced by electronic and steric properties of both the metal complexes moiety and the silyl group. ²⁹Si NMR spectroscopic investigation of complexes with different ligands L or substituents R and R′, and structure analyses reveal, that the coupling constant J(SiMnH) and the MnSi distance are especially good indicators for changes in the bonding situation. Electron-donating ligands and/or electronegative substituents R favour addition of SiR₃, as indicated by small J(SiMnH) values and short MnSi distances in the particular complexes. By means of a neutron diffraction study of MeCp(CO)₂Mn(H)SiFPh₂ (1) (MnSi 235.2(4), MnH 156.9(4), SiH 180.2(5) pm) and X-ray structure analyses of MeCp(CO)(PMe₃)Mn(H)SiHPh₂ (2) (MnSi 232.7(1) pm) and C₅Me₅(CO)₂Mn(H)SiHPh₂ (3) (MnSi 239.5(1) pm) structural parameters which are typical for the three-center bonds, are discussed. By comparison of known structures the reaction pathway for the oxidative addition (reductive elimination) of silanes can be derived.     

Author index

The reduction of ([C₅Me₅(CO)₂Ru]₂ with Na/K alloy provides a suitable way to the potassium ruthenate K[Ru(CO)₂C₅Me₅] (2). 2 reacts readily with HCl, MeI, MeOCH₂Cl, HSiCl₃ and t-BuPCl₂ to give the corresponding complexes C₅Me₅(CO)RuX (X = H, Me, CH₂OMe, Si(H)Cl₂, P(t-Bu)Cl) containing a Main Group element—ruthenium-σ-bond. HCl transforms C₅Me₅(CO)₂RuCH₂OMe into C₅Me₅(CO)₂RuCH₂Cl, which undergoes a complex redox reaction in the presence of 2 or Na[Fe(CO)₂C₅Me₅] .     

NMR-spektroskopische Untersuchungen an Undecamethylcyclohexasilanyl-Derivaten

The structure and ²⁹Si chemical shifts of nine undecamethylcyclohexasilanyl derivatives, Si₆Me₁₁X (X = Fe(CO)₂cp, SO₃CF₃, F, Cl, Br, I, H, C CH, OH), have been assigned using ¹J_SiSi and ²J_SiSi derived from ²⁹Si-INADEQUATE and ²⁹Si-INEPT-INADEQUATE and ²⁹Si-INEPT-INADEQUATE NMR spectra. Only the halo-derivatives exhibit linear correlation between ¹J_SiSi and Pauling electronegativities. The correlation of other derivatives is improved by employing Inamato's inductivity values. A new synthetic route to Si₆Me₁₁X (X = F, Cl, Br, I) has been developed.     

29Si NMR Spektroskopie von Cyclopentasilanen

The structure and ²⁹Si chemical shifts of the halodimethylsilylnonamethylcyclopentasilanes Si₅Me₉SiMe₂X (1–4) and the halononamethylcyclopentasilanes Si₅Me₉X (5–8) (X = F, Cl, Br, I) have been assigned using ¹J(SiSi) and ²J(SiSi) coupling constants derived from ²⁹Si-INADEQUATE and ²⁹Si-INEPT—INADEQUATE NMR spectra. The compounds exhibit good correlation between chemical shift, ¹J(SiSi) and Pauling electronegativities.     

The syntheses and coordination properties of M(CO)3X(DAB) (M = Mn,Re; X = Cl,Br, I; DAB = 1,4-diazabutadiene)

M(CO)₅X (M = Mn, Re; X = Cl, Br, I) reacts with DAB (1,4-diazabutadiene = R₁N=C(R₂)C(R₂)′=NR′₁) to give M(CO)₃X(DAB). The ¹H, ¹³C NMR and IR spectra indicate that the facial isomer is formed exclusively. A comparison of the ¹³C NMR spectra of M(CO)₃X(DAB) (M = Mn, Re; X = Cl, Br, I; DAB = glyoxalbis-t-butylimine, glyoxyalbisisopropylimine) and the related M(CO)₄DAB complexes (M = Cr, Mo, W) with Fe(CO)₃DAB complexes shows that the charge density on the ligands is comparable in both types of d⁶ metal complexes but is slightly different in the Fe-d⁸ complexes. The effect of the DAB substituents on the carbonyl stretching frequencies is in agreement with the A′(cis) > A″ (cis) > A′(trans) band ordering.Mn(CO)₃Cl(t-BuNCHCHNt-Bu) reacts with AgBF₄ under a CO atmosphere yielding [Mn(CO)₄(t-BuNCHCHN-t-Bu)]BF₄. The cationic complex is isoelectronic with M(CO)₄(t-BuNCHCHNt-Bu) (M = Cr, Mo, W).     

Neue Rhodium(I)‐Komplexe mit Donor/Akzeptor‐Chelatliganden

Alternative Ligands. XXXVI. Novel Rhodium(I) Complexes with Donor/Acceptor Chelating Ligands In order to generate metal base/Lewis‐acid interactions in rhodium(I) phosphane complexes the binuclear complex [Rh(CO)₂Cl]₂ was reacted in benzene with dipod ligands of the type R₂M′(OCH₂PMe₂)_x(CH₂CH₂PMe₂)_2–x (R = F, Me; M′ = Si, Ge; x = 0–2) using the Ziegler dilution principle with the aim to produce mononuclear compounds in which with formation of five‐membered chelate rings in principle Rh → M′ contacts are possible. The reactions of ligands 1 – 7 (Table 1) with [Rh(CO)₂Cl]₂ proceed under CO elimination and, in spite of large turnovers, lead to a variety of products 8 – 14 (Table 1), in case of 11 , 13 and 14 accompanied by degradation of the corresponding ligands. Intact ligands are present in the 16‐membered rings of the binuclear complexes 8 – 10 and 12 , for which, due to the molecular structure, Rh → M′ interactions can be excluded. In the reaction of Me₂Si(OCH₂PMe₂)₂ ( 4 ) with [Rh(CO)₂Cl]₂ the unusual binuclear system 11 with a central Rh₂O₂ four‐membered ring and two RhO(SiMe₂OCH₂PMe₂) six‐membered rings is formed. Small amounts of the mononuclear compounds Rh(CO)Cl(Me₂PCH₂OH)₂ ( 13 ) and Rh(CO)Cl₃(Me₂PCH₂OH)₂ ( 14 ), respectively, are obtained in crystalline form from the reaction mixtures of [Rh(CO)₂Cl]₂ with Me₂Ge(OCH₂PMe₂)(CH₂CH₂PMe₂) ( 6 ) or Me₂Ge(OCH₂PMe₂)₂ ( 7 ). The new complexes were characterized by analytic (C, H), spectroscopic (NMR, IR, MS) and, except for 12 , by single crystal structural analyses.     

Zur reaktion von metall-koordiniertem kohlenmonoxid mit yliden: XI. Einige neuartige η1-vinyl-komplexe des eisens durch deprotonierung kationischer carbenkomplexe mit trimethyl(methylen)phosphoran

Novel η¹-vinyl complexes of the type Cp(CO)(L)FeC(OMe)C(R)R′ (R = R′ = H, Me; R = H, R′ = Me; L = Me₃P, Ph₃P) are obtainied via methylation of the acyl complexes Cp(CO)(L)FeC(O)R (R = Me, Et, i-Pr) with MeOSO₂F and subsequent deprotonation of the resulting carbene complexes [Cp(CO)(L)FeC(OMe)R]SO₃F with the phosphorus ylide Me₃PCH₂. The same procedure can be applied for the synthesis of the pentamethylcyclopentadienyl derivative C₅Me₅(CO)(Me₃P)FeC(OMe)CH₂, while treatment of the hydroxy or siloxy carbene complexes [Cp(CO)(L)FeC(OR)Me]X (R = H, Me₃Si; X = SO₃CF₃) with Me₃CH₂ results in the transfer of the oxygen bound electrophile to the ylidic carbon. Some remarkable spectroscopic properties of the new complexes are reported.     

Synthese und reaktivität von silicium-übergangsmetall-komplexen: XVIII. Trihydrosilylkomplexe des eisens: Darstellung und metallierung mit dicobaltoctacarbonyl

The reaction of the silyl complex Cp(CO)₂FeSiH₃ (1) with various donors under photochemical conditions leads to the formation of Cp(CO)(L)FeSiH₃ (2a-2c) and Cp(L)₂FeSiH₃ (3a, 3b) (L = MeNC, t-BuNC, Me₃P) via stepwise CO-substitution. 2a,2b are transformed by Co₂(CO)₈ to the complexes μ₂-[Cp(CO)-(RNC)FeSiH] [μ²-(CO)] Co₂(CO)₆ (3a,3b), the first complexes with a hydrogen substituted ferrio-silanediyl unit bridging two cobalt atoms.     

Übergangsmetall—silyl-komplexe: VI. CH3/Cl-Austausch bei der reaktion vonR3PAuCH3 mit chlorsilanen

The reaction of R₃PAuCH₃ (R₃P = TolPh₂P or Me₂PhP) with organosilicon halides HSiR₂Cl (HSiPh₂Cl, HSiMeCl₂, HSiMe₂Cl) yields R₃PAuCl and the corresponding methylated silanes HSiR₂CH₃ by CH₃/Cl exchange. Oxidative addition of the SiH group of several H-silanes to the gold center is not observed.     

Small ring metallocycles : V. Crystal and molecular structure of hydrido-1,3-(1,1,3,3-tetramethyldisiloxanediyl)carbonylbis(triphenylphosphine)iridium(III), Me2SiOSiMe2Ir(H)(CO)(PPh3)2 · EtOH

The structure of the cyclo-metalladisiloxane, Me₂SiOSiMe₂Ir(H)(CO)(PPh₃)₂, has been determined by single crystal X-ray diffraction using Mo-K_α radiation. Data were collected to 20 = 45 ° giving 6060 unique reflections,of which 4582 had I ?3σ(I). The latter were used in the full-matrix refinement. Crystallographic data: space group, P$\text{1}$; cell constants: 12.604(7),12.470(4), 15.821(6) Å, 66.93(6)°, 105.34(7)°, 112.41(8)°;V 2095(3) ų; p(obs) 1.45 g/cm³; p(calc) 1.46g/cm³ (Z=2). The asymmetric unit consists of one iridium complex and one molecule of ethanol of salvation. The structure was solved by standard heavy atom methods and refined with all non-hydrogen atoms anisotrophic to final R factors, R₁ 0.034 and R₂ 0.042. The iridium metallocycle has approximate C_s symmetry with the mirror plane passing through the four-membered IrSiOSi ring. The average IrP, IrSi and SiO bond lengths are 2.38, 2.41, and 1.68 Å, respectively. The IrCO and CO bond lengths are 1.903(8) and 1.133(8). The H atom bonded to Ir was not located.The Ir atom is raised out of the basal, P₂Si₂ plane toward the carbonyl by about 0.26 Å. The most striking feature of the structure is the strain apparent in the four-membered ring. The internal angels are: 64.7 (SiIrSi), 96.8 (IrSiO), 97.8 (IrSiO), and 99.8 (SiOSi). In an unstrained molecule, the SiOSi angle is normally in the 130–150° range. It is proposed that the strain in the ring is consistent with the catalytic activity of the metallocycle.     

Übergangsmetall-substituierte phosphane,arsane und stibane : XXIX. Metallierte arsane und stibane mit chiralem eisen-substituenten

The reaction of Cp(CO)₂FeEMe₂ (E  As, Sb, Bi) with Me₃P, Et₃P, Me₂PhP and (MeO)₃P leads to a CO/R₃P exchange and formation of the chiral derivatives Cp(CO)(R₃P)FeEMe₂. Cp(CO)[(MeO)₃P]FeEMe₂ rearranges already at room temperature to Cp(CO)[(Me₃E]FeP(O)(OMe)₂ which is transformed by (MeO)₃P to Cp(CO)[(MeO)₃P]FeP(O)(OMe)₂. The high nucleophilicity of the new organometallic Lewis bases is established by the easy conversion of Cp(CO)(Me₃P)FeSbMe₂ to [Cp(CO)(Me₃P)Fe(SbMe₃)]I with MeI, or to [Cp(CO)(Me₃P)FeSbMe₂Fe(CO)LCp]Hal (L  CO, Hal  Cl; L  Me₃P, Hal  Br) with Cp(CO)LFe-Hal, respectively. The new compounds are characterized by spectroscopy and elementary analyses.     

The preparation of functional alkylidynetricobalt nonacarbonyl complexes from dicobalt octacarbonyl

Various functionally-substituted methylidynetricobalt nonacarbonyl derivatives, RCCo₃(CO)₉, where R is D, Me₃Si, PhMe₂Si, (MeO)₂P(O), (EtO)₂P(O), Me₃COC(O), Me₃SiOC(O), Et₂NC(O), CH₃C(O), C₂H₅C(O), n-C₃H₇C(O), Me₂-CHC(O), n-C₄H₉C(O), Me₃C(O), PhC(O), p-CH₃C₆H₄C(O), p-BrC₆H₄C(O), HOCH₂, HC(O), CH₃O and Me₂N, have been prepared by reaction of dicobalt octacarbonyl with the appropriate RCX₃ or RCHX₂ (XCl or Br) compound.     

Alternativ-Liganden. XXII. Rhodium(I)-Komplexe mit Donor/Akzeptor-Liganden des Typs Me2PCH2CH2SiXnMe3−(X = F,Cl, OMe)

Alternative Ligands. XXII. Rhodium(I) complexes with Donor/Acceptor Ligands of the Typs Me₂PCH₂CH₂SiX_nMe_3?n(X = F, Cl, OMe) Donor/acceptor ligand of the type Me₂PCH₂SiX_nMe_3?n react with [Rh(CO)₂Cl]₂ ( 1 ) to give the mononuclear complexes RhCl(CO)(PMe₂CH₂CH₂SiX_nMe_3?n)₂ ( 2-6 , Table 1) with planar geometry of the donor atoms, one exception being Me₂PCH₂CH₂CH₂SiCl₃, yielding the crystalline Rh^III-complex RhCl₂(CO)(PMe₂CH₂CH₂SiCl₂)(PMe₂CH₂CH₂SiCl₃) ( 7 ) by oxidative addition of one of the SiCl bonds to the Rh¹ precursor. Structures with Rh → Si interaction between the basic central atoms and the acceptor group SiX_nMe_3?n could be detected in the isolated products neither spectroscopically nor by X-ray diffraction of the two representatives RhCl(CO)(PMe₂CH₂CH₂SiF₃)₂ ( 2 ) and RhCl(CO)[PMe₂CH₂CH₂siF₃]₂ ( 2 ) and RhCl(CO) [PMe₂CH₂CH₂Si(OMe₃]₂ ( 6 ). The presence of such acid/base adducts in the reaction mixture is indicated for the more acidic acceptor groups SiX_nMe_3?n byv_co values near 1990cm^?1, (see Table 3). The complex RhCl(CO)PMe₃)(PMe₂CH₂CH₂SiF₃ ( 8 ) is obtained by the reaction of RhCl(CO)(PMe₃)₂ ( 9 ) with Me₂PCH₂SiF₃ and has been identified spectroscopically in a mixture with 2 and 9 .     

X-ray structure of Fe{C(CF3)2(OH)}(CO)2(η-C5H5), a complex containing a substituted hydroxymethyl ligand

An X-ray structure determination on Fe{C(CF₃)₂(OH)}(CO)₂(η-C₅H₅), obtained by protonating the product from Na[Fe(CO)₂(η-C₅H₅)] and (CF₃)₂CO, showed the crystal to contain discrete molecules. There are substantial intramolecular OH…FCF₂ bonds but only weak intermolecular OH…O interactions. Important distances are: FeC 2.060(6), CCF₃ 1.505(9), COH 1.435(7), CF…HO 2.131(6), 2.485(6) Å.