Zur Chemie des Dimesityleisens. X. Mesityleisenkomplexe [FeMes(X)]2 mit zentraler {Fe2(μ-Mes)2}-Einheit (Mes = C6H2-2,4,6-(CH3)3)

Chemistry of Dimesityl Iron. X. Mesityl Iron Complexes [FeMes(X)]₂ with a Central {Fe₂(μ-Mes)₂} Unit (Mes = C₆H₂-2,4,6-(CH₃)₃) Dimeric complexes [{MesFe(OAryl)}₂] with coordination number (CN) of 3 are obtained from Fe₂Mes₄ 1 by partial acidolyses with 2,6-di-tert-butyl-substituted phenols (HOAryl). 1 reacts with 1,3-diketones in a molar ratio of 1:2 to [{MesFe(diketonate)}₂] with CN 4. A central {Fe₂(μ-Mes)₂}-unit with short Fe—Fe distances of 2.56 to 2.63 Å ( 1: 2.615 Å) is found in both types of complexes. The mixed ligand complexes react with an excess of phenol or diketone to {Fe(OAryl)₂} or {Fe(diketonate)₂}, respectively. 1 reacts with HOAryl in the molar ratio of 1:1 to [Fe₂(μ-Mes)₂Mes(OAryl)]. The structures of [Fe₂(μ-Mes)₂(OC₆H₂-2,6-tBu₂-4-CH₃)₂] ( 3 ), [Fe₂(μ-Mes)₂Mes(OC₆H₂-2,4,6-tBu₃)] ( 5 ) and [Fe₂(μ-Mes)₂{(tBuCO)₂CH}₂] ( 9 ) are presented.     

Beiträge zur Organolanthanidchemie. III [1]. Darstellung und Eigenschaften von 1,4-Diaryl-1,3-butadien-Komplexen der Lanthanide

Contributions to Organolanthanide Chemistry. III. Synthesis and Properties of 1,4-Diaryl-1,3-butadiene Lanthanide Complexes Cyclopentadienyllanthanide halides react with 1,4-diarylbutadienes in the presence of alkali metals to give Cp*La(1,4-Ph₂C₄H₄) · DME ( I ), Cp*La(1,4-{o-CH₃O? C₆H₄}₂ · C₄H₄) · 2DME ( II ), [Li(THF)₃][Sm(1,4-Ph₂C₄H₄)₂] ( III ), [Li(DME)][(1,4-{p-CH₃? C₆H₄}₂C₄H₄)LuCl₂] ( IV ) and [Li(DME)][(1,4-{o-CH₃O? C₆H₄}₂C₄H₄)LuCl₂] ( V ). Samariumtrichloride reacts with 1,4-diphenyl-butadiene and lithium in tetrahydrofurane with formation of [Li(THF)₄][Sm(1,4-Ph₂C₄H₄)₂] ( VI ). Reaction of samarium with the p-tolyl derivative in the presence of iodine gives (1,4-{p-CH₃? C₆H₄}₂C₄H₄)SmI · 3THF ( VII ). The compounds were characterized by elementary analysis, i.r., ¹H- and ¹³C- n.m.r., and EI-MS spectra.     

Homoleptische Amide von Zink,Cadmium und Quecksilber

Homoleptic Amides of Zinc, Cadmium, and Mercury ZnCl₂, CdCl₂ and HgCl₂ react with the lithium salts ( 1 a–5 a ) of the sterically demanding secundary amines HN(SiMe₃)Ph ( 1 ), HN(SiMe₃)C₆H₃Me₂‐2,6 ( 2 ), HN(SiMe₃)C₆H₃ⁱPr₂‐2,6 ( 3 ), HN(SiMe₃)C₆H₃^tBu₂‐2,5 ( 4 ), and HN(SiMe₂NMe₂)C₆H₃ⁱPr₂‐2,6 ( 5 ) yielding the corresponding homoleptic metal amides Zn[N(SiMe₂R′)R]₂ ( 1 b–5 b ), Cd[N(SiMe₂R′)R]₂ ( 1 c , 5 c ), and Hg[N(SiMe₂R′)R]₂ ( 1 d–5 d ), respectively. Except the dimeric {Zn[N(SiMe₃)Ph]₂}₂ ( 1 b ), all complexes are monomeric. The compounds were characterized by elemental analyses, molecular weight determinations, NMR and mass spectra. Furthermore, the zinc amides ( 1 b–5 b ) and the mercury amides 1 d–3 d and 5 d were characterized by single crystal X‐ray structure analysis. Except 1 b and 5 b , they show a linear N–M–N arrangement.     

Reaktionen von Zink- und Cadmiumhalogeniden mit Tris(trimethylsilyl)phosphan und Tris(trimethylsilyl)arsan

Reactions of Zinc and Cadmium Halides with Tris(trimethylsilyl)phosphane and Tris(trimethylsilyl)arsane ZnCl₂ reacts with E(SiMe₃)₃ (E = P, As) in toluene in the presence of PⁿPr₃ to give the binuclear complexes [Zn₂Cl₂{E(SiMe₃)₂}₂(PⁿPr₃)₂] · C₇H₈ (E = P 1 , As 2 ). Therefore by the use of PⁱPr₃ clusters consisting of ten metal atoms are obtained, [Zn₁₀Cl₁₂(ESiMe₃)₄(PⁱPr₃)₄] (E = P 3 , As 4 ). As a result of the reaction of CdBr₂ with P(SiMe₃)₃ the compound [CdBr₂{P(SiMe₃)₃}]₂ ( 5 ) can be isolated at –40 °C. In the presence of PⁿPr₃ CdBr₂ reacts with P(SiMe₃)₃ forming the binuclear complex [Cd₂Br₂{P(SiMe₃)₂}₂(PⁿPr₃)₂] · thf ( 6 ). The same reaction with PⁱPr₃ yields to the cluster [Cd₁₀Br₁₂(PSiMe₃)₄{P(SiMe₃)₃}₄] · 2 C₇H₈ ( 7 ). ZnI₂ and CdI₂ react with As(SiMe₃)₃ to yield the complexes [MI₂{As(SiMe₃)₃}]₂ (M = Zn 8 , Cd 9 ). In the case of CdI₂ additionally the cluster [Cd₁₀I₁₂(AsSiMe₃)₄ · {As(SiMe₃)₃}₄] · 4,5 C₇H₈ ( 10 ) is formed which is analogous to the compounds 3 , 4 and 7 . In the presence of [PⁿBu₄]I 8  reacts in THF to give the ionic compound [PⁿBu₄]₂[Zn₆I₆(AsSiMe₃)₄(thf)₂] · C₆H₆ ( 11 ).     

Bonding in Barium Boryloxides,Siloxides, Phenoxides and Silazides: A Comparison with the Lighter Alkaline Earths

Barium complexes ligated by bulky boryloxides [OBR₂]⁻ (where R=CH(SiMe₃)₂, 2,4,6-ⁱPr₃-C₆H₂ or 2,4,6-(CF₃)₃-C₆H₂), siloxide [OSi(SiMe₃)₃]⁻, and/or phenoxide [O-2,6-Ph₂-C₆H₃]⁻, have been prepared. A diversity of coordination patterns is observed in the solid state for both homoleptic and heteroleptic complexes, with coordination numbers ranging between 2 and 4. The identity of the bridging ligand in heteroleptic dimers [Ba(μ₂-X₁)(X₂)]₂ depends largely on the given pair of ligands X₁ and X₂. Experimentally, the propensity to fill the bridging position increases according to [OB{CH(SiMe₃)₂}₂)]⁻<[N(SiMe₃)₂]⁻<[OSi(SiMe₃)₃]⁻<[O(2,6-Ph₂-C₆H₃)]⁻<[OB(2,4,6-ⁱPr₃-C₆H₂)₂]⁻. This trend is the overall expression of 3 properties: steric constraints, electronic density and σ- and π-donating capability of the negatively charged atom, and ability to generate Ba ⋅ ⋅ ⋅ F, Ba ⋅ ⋅ ⋅ C(π) or Ba ⋅ ⋅ ⋅ H−C secondary interactions. The comparison of the structural motifs in the complexes [Ae{μ₂-N(SiMe₃)₂}(OB{CH(SiMe₃)₂}₂)]₂ (Ae = Mg, Ca, Sr and Ba) suggest that these observations may be extended to all alkaline earths. DFT calculations highlight the largely prevailing ionic character of ligand-Ae bonding in all compounds. The ionic character of the Ae-ligand bond encourages bridging coordination, whereas the number of bridging ligands is controlled by steric factors. DFT computations also indicate that in [Ba(μ₂-X₁)(X₂)]₂ heteroleptic dimers, ligand predilection for bridging vs. terminal positions is dictated by the ability to establish secondary interactions between the metals and the ligands.     

Phosphaniminato‐Cluster von Eisen. Die Kristallstrukturen von [FeCl(NPEt3)]4, [Fe(C=C–SiMe3)(NPEt3)]4 und [Fe3Cl4{NP(NMe2)3}3]

Phosphoraneiminato Cluster of Iron. The Crystal Structures of [FeCl(NPEt₃)]₄, [Fe(C=C–SiMe₃)(NPEt₃)]₄, and [Fe₃Cl₄{NP(NMe₂)₃}₃] The reaction of iron dichloride with the silylated phosphaneimine Me₃SiNPEt₃ in the presence of potassium fluoride at 165 ?C leads to the phosphoraneiminato complex [FeCl(NPEt₃)]₄ ( 1 ). Compound 1 forms black, moisture and oxygen sensitive crystals. According to the crystal structure analysis 1 has a heterocubane structure, in which the iron and the nitrogen atoms of the NPEt₃^– groups occupy the corners of a distorted cube and form Fe–N–Fe bond angles of 83.1? and N–Fe–N angles of 96.5?. This results in significantly short Fe…Fe contacts of 272.9 pm. The results of magnetic susceptibility measurements in the range of temperatures from 1.8 to 293 K and the ⁵⁷Fe‐Mössbauer spectra in the range of temperatures from 2 to 300 K are reported. Compound 1 reacts with the lithiated acetylenes LiC=C–CMe₃ and LiC=C–SiMe₃ in n‐hexane to form the iron‐organic derivatives [Fe(C=C–R)(NPEt₃)]₄ [R = CMe₃ ( 2 a ), R = SiMe₃ ( 2 b )] keeping the heterocubane structure. Compounds 2 a and 2 b form crystals which are very reactive and also black. According to the crystal structure analysis 2 b has a Fe₄N₄ heterocubane structure which is less distorted than that in 1 with bond angles Fe–N–Fe of 85.5? and N–Fe–N of 94.2?. This leads to the longer Fe…Fe contacts of 281.4 pm. With the dimethylamido derivative Me₃SiNP(NMe₂)₃ iron dichloride reacts under conditions similar to those in the synthesis of 1 to form the dark green mixed‐valenced Fe^II/Fe^III cluster [Fe₃Cl₄{NP(NMe₂)₃}₃] ( 3 ). According to the crystal structure analysis the three iron atoms in 3 are connected via one μ₃‐N atom of a NP(NMe₂)₃^– ligand, via two μ‐N atoms of the two remaining phosphoraneiminato ligands, and via one μ‐Cl atom to form an incomplete heterocubane skeleton.     

Synthese und Kristallstrukturen neuer phosphorverbrückter bimetallischer Cluster der Elemente Quecksilber und Eisen

Synthesis and Crystal Structures of New Phosphorus‐bridged Bimetallic Clusters of the Elements Mercury and Iron The reaction of [Fe(CO)₄(HgX)₂] (X = Cl, Br) with P(SiMe₃)₂^tBu in the presence of tertiary phosphines and phosphinium salts leads to the ionic compounds [PPh₄]₂[Hg₁₂{Fe(CO)₄}₈(P^tBu)₄X₂] (X = Cl, Br) ( 1 , 2 ). If [Fe(CO)₄(HgX)₂] reacts with P(SiMe₃)₂^tBu the polymeric polynuclear complex [Hg₁₅{Fe(CO)₄}₃(P^tBu)₈Br₈]n ( 3 ) as well as the twenty mercury‐ and eight iron‐atoms containing [Hg₂₀{Fe(CO)₄}₈(P^tBu)₁₀X₄]‐clusters (X = Br, Cl) ( 4 , 5 ) are formed. The reaction of [Fe(CO)₄(HgX)₂] with LiPPh₂ yields to the phosphanido‐bridged [Hg₄{Fe(CO)₄}₂(PPh₂)₂Cl₂] ( 6 ), where as the use of LiP(SiMe₃)Ph leads to the diphosphinidene‐bridged cluster [Li(thf)₄]₂[Hg₁₀{Fe(CO)₄}₆(P₂Ph₂)₂Br₆] ( 7 ). The structures of the compounds 1–7 were characterized by X‐ray single crystal structure analysis.     

Synthese und Kristallstrukturen der Bismutchalkogenolate Bi(SC6H5)3, Bi(SeC6H5)3 und Bi(S‐4‐CH3C6H4)3

Synthesis and Crystal Structures of Bismuth Chalcogenolato Compounds Bi(SC₆H₅)₃, Bi(SeC₆H₅)₃, and Bi(S‐4‐CH₃C₆H₄)₃ Bismuth(III) acetate reacts with thiophenol in ethyl alcohol at 80 °C to yield Bi(SC₆H₅)₃ ( 1 ). Slow cool down of the deep yellow mixture lead to the formation of orange crystals of 1 . The homotype phenylselenolato compound of bismuth Bi(SeC₆H₅)₃ ( 2 ) has been prepared by the reaction of BiX₃ (X = Cl, Br) with Se(C₆H₅)SiMe₃ in diethyl ether. In the same way as Bi(SC₆H₅)₃ ( 1 ) the reaction between bismuth(III) acetate and 4‐tolulenethiole results in red crystals of Bi(S‐4‐CH₃C₆H₄)₃ ( 3 ). In consideration of three longer Bi–E distances (intermolecular interactions, E = S; Se) the Bi(EPh)₃ molecules form via face‐linked octahedra 1‐dimensional chains in the crystal lattice, while for 3 the 1‐dimensional chain is formed by face‐linked trigonal prisma. We reported herein the synthesis and structures of Bi(SC₆H₅)₃ ( 1 ), Bi(SeC₆H₅)₃ ( 2 ), and Bi(S‐4‐CH₃C₆H₄)₃ ( 3 ).     

Rare earth metal complexes based on β-diketiminato and novel linked bis(β-diketiminato) ligands: Synthesis, structural characterization and catalytic application in epoxide/CO2-copolymerization

Mesityl substituted β-diketiminato lanthanum and yttrium complexes [(BDI)Ln{N(SiRMe₂)}₂] (BDI = ArNC(Me)CHC(Me)NAr, Ar = 2,4,6-Me₃C₆H₂, Ln = La, R = Me (1), H (2a); Ln = Y, R = H (2b)) can be prepared via facile amine elimination starting from [La{N(SiMe₃)₂}₃] and [Ln{N(SiHMe₂)₂}₃(THF)₂] (Ln = Y, La), respectively. The X-ray crystal structure analysis of 1 revealed a distorted tetrahedral geometry around lanthanum with a η²-bound β-diketiminato ligand. A series of novel ethylene- and cyclohexyl-linked bis(β-diketiminato) ligands [C₂H₄(BDI^Ar)₂]H₂ and [Cy(BDI^Ar)₂]H₂ [Ar = Mes (=2,4,6-Me₃C₆H₂), DEP (=2,6-Et₂C₆H₃), DIPP (=2,6-i-Pr₂C₆H₃)] were synthesized in a two step condensation procedure. The corresponding bis(β-diketiminato) yttrium and lanthanum complexes were obtained via amine elimination. The X-ray crystal structure analysis of the ethylene-bridged bis(β-diketiminato) complex [{C₂H₄(BDI^Mes)₂}YN(SiMe₃)₂] (3b) and cyclohexyl-bridged complexes [{Cy(BDI^Mes)₂}LaN(SiHMe₂)₂] (7) and [{Cy(BDI^DEP)₂}LaN(SiMe₃)₂] (8) revealed a distorted square pyramidal coordination geometry around the rare earth metal, in which the amido ligand occupies the apical position and the two linked β-diketiminato moieties form the basis. The geometry of the bis(β-diketiminato) ligands depends significantly on the linker unit. While complexes with an ethylene-linked ligand adopt a cisoid arrangement of the two aromatic substituents, complexes with cyclohexyl linker adopt a transoid arrangement. Either one (3b) or both (7, 8) of the β-diketiminato moieties are tilted out of the η² coordination mode, resulting in close Ln?C contacts. The β-diketiminato and linked bis(β-diketiminato) complexes were moderately active in the copolymerization of cyclohexene oxide with CO₂. A maximum of 92% carbonate linkages were obtained using the ethylene-bridged bis(β-diketiminato) complex [{C₂H₄(BDI^Mes)₂}LaN(SiHMe₂)₂] (4).     

Aminostannanes and aminostannylenes containing a C,N-chelated ligand

Aminotin(II and IV) compounds {[(2,6-i-Pr-C₆H₃)(H)N]-μ-(Sn)-Cl}₂, {2-[(CH₃)₂NCH₂]C₆H₄}₂Sn[N(H)(2,6-i-Pr-C₆H₃)]₂ and {2-[(CH₃)₂NCH₂]C₆H₄}Sn[N(2,6-i-Pr-C₆H₃)(SiMe₃)] were prepared by lithium halide elimination from tin halides and corresponding lithium complexes. [(2,6-i-Pr-C₆H₃)(H)N]Li (1) reacts with one half of molar equivalent of SnCl₂ to give {[(2,6-i-Pr-C₆H₃)(H)N]-μ-(Sn)-Cl}₂. The same lithium amide (1) gave with R₃SnCl corresponding aminostannanes. Further reactions of these compounds with n-butyllithium gave the starting 1 and tetraorganostannanes. {2-[(CH₃)₂NCH₂]C₆H₄}₂SnBr₂ reacts with two equivalents of 1 to {2-[(CH₃)₂NCH₂]C₆H₄}₂Sn[N(H)(2,6-i-Pr-C₆H₃)]₂. The dimeric heteroleptic stannylene {[(2,6-i-Pr-C₆H₃)(SiMe₃)N](μ₂-Cl)Sn}₂ reacts with 2-[(CH₃)₂NCH₂]C₆H₄Li to the monomeric {2-[(CH₃)₂NCH₂]C₆H₄}Sn[N(2,6-i-Pr-C₆H₃)(SiMe₃)]. The structure in the solid state and in solution and reactivity of products is also discussed. The unique decatin cluster has been isolated by hydrolysis of {[(2,6-i-Pr-C₆H₃)(H)N]-μ-(Sn)-Cl}₂. The structure of some compounds was also evaluated by theoretical DFT methods.     

Subvalente Galliumtriflate – mögliche Ausgangsverbindungen für Clusterverbindungen des Galliums

Subvalent Gallium Triflates – Potentially Useful Starting Materials for Gallium Cluster Compounds By reaction of GaCp* with trifluormethanesulfonic acid in hexane a mixture of gallium trifluormethanesulfonates (triflates, OTf) is obtained. This mixture reacts readily with lithiumsilanides [Li(thf)₃Si(SiMe₃)₂R] (R = Me, SiMe₃) to afford the cluster compounds [Ga₆{Si(SiMe₃)Me}₆], [Ga₂{Si(SiMe₃)₃}₄] and [Ga₁₀{Si(SiMe₃)₃}₆]. By crystallization from various solvents the gallium triflates [Ga(OTf)₃(thf)₃], [HGa(OTf)(thf)₄]⁺ [Ga(OTf)₄(thf)₃]⁻, [Cp*GaGa(OTf)₂]₂ and [Ga(toluene)₂]⁺ [Ga₅(OTf)₆(Cp*)₂]⁻ were isolated and characterized by single crystal X ray structure analysis.     

Diradicaloid or Zwitterionic Character: The Non‐Tetrahedral Unsaturated Compound [Si4{N(SiMe3)Dipp}4] with a Butterfly‐type Si4 Substructure

The reduction of the tribromoamidosilane {N(SiMe₃)Dipp}SiBr₃ (Dipp=2,6‐i Pr₂C₆H₃) with potassium graphite or magnesium resulted in the formation of [Si₄{N(SiMe₃)Dipp}₄] ( 1 ), a bicyclo[1.1.0]tetrasilatetraamide. The Si₄ motif in 1 does not adopt a tetrahedral substructure and exhibits two three‐coordinate and two four‐coordinate silicon atoms. The electronic situation on the three‐coordinate silicon atoms is rationalized with positive and negative polarization based on EPR analysis, magnetization measurements, and DFT calculations as well as ²⁹Si CP MAS NMR and multinuclear NMR spectroscopy in solution. Reactivity studies with 1 and radical scavengers confirmed the partial charge separation. Compound 1 reacts with sulfur to give a novel type of silicon sulfur cage compound substituted with an amido ligand, [Si₄S₃{N(SiMe₃)Dipp}₄] ( 2 ).     

Metallorganische Verbindungen der Lanthanoide. 88. Monomere Lanthanoid(III)-amide: Synthese und Röntgenstrukturanalyse von [Nd{N(C6H5)(SiMe3)}3(THF)], [Li(THF)2(μ-Cl)2Nd{N(C6H3Me2-2,6)(SiMe3)}2(THF)] und [ClNd{N(C6H3-iso-Pr2-2,6)(SiMe3)}2(THF)]

Organometallic Compounds of the Lanthanides. 88. Monomeric Lanthanide(III) Amides: Synthesis and X-Ray Crystal Structure of [Nd{N(C₆H₅)(SiMe₃)}₃(THF)], [Li(THF)₂(μ-Cl)₂Nd{N(C₆H₃Me₂-2,6)(SiMe₃)}₂(THF)], and [ClNd{N(C₆H₃-iso-Pr₂-2,6)(SiMe₃)} ₂(THF)] A series of lanthanide(III) amides [Ln{N(C₆H₅) · (SiMe₃)}₃(THF)_x] [Ln = Y ( 1 ), La ( 2 ), Nd ( 3 ), Sm ( 4 ), Eu ( 5 ), Tb ( 6 ), Er ( 8 ), Yb ( 9 ), Lu ( 10 )] could be prepared by the reaction of lanthanide trichlorides, LnCl₃, with LiN(C₆H₅)(SiMe₃). Treatment of NdCl₃(THF)₂ and LuCl₃(THF)₃ with the lithium salts of the bulky amides [N(C₆H₃R₂-2,6)(SiMe₃)]^? (R = Me, iso-Pr) results in the formation of the lanthanide diamides [Li(THF)₂(μ-Cl)₂Nd{N(C₆H₃Me₂-2, 6)(SiMe₃)}₂(THF)] ( 11 ) and [ClLn{N(C₆H₃-iso-Pr₂-2,6)(SiMe₃)} ₂(THF)] [Ln = Nd ( 12 ), Lu ( 13 )], respectively. The ¹H- and ¹³C-NMR and mass spectra of the new compounds as well as the X-ray crystal structures of the neodymium derivatives 3 , 11 and 12 are discussed.     

Das Hexagallan [Ga6{SiMe(SiMe3)2}6] und das closo‐Hexagallanat [Ga6{Si(CMe3)3}4(CH2C6H5)2]2— — der Übergang zu einem ungewöhnlichen precloso‐Cluster

The Hexagallane [Ga₆{SiMe(SiMe₃)₂}₆] and the closo‐Hexagallanate [Ga₆{Si(CMe₃)₃}₄ (CH₂C₆H₅)₂]^2— — the Transition to an Unusual precloso‐Cluster The closo hexagallanate [Ga₆R₄(CH₂Ph)₂]^2— (R = Si^tBu₃) as well as the hexagallane Ga₆R₆ (R = SiMe(SiMe₃)₂) with only six cluster electron pairs were isolated from reactions of “GaI” with the corresponding silanides. The structure of the latter is derived from an octahedron by a Jahn‐Teller‐distortion and is different from the capped trigonal bipyramidal one expected by the Wade‐Mingos rules. Both compounds were characterized by X‐ray crystallography. The bonding is discussed with simplified Ga₆H₆ and Ga₆H₆^2— models via DFT methods.     

Reaction of aryl azides with tris(trimethylsilyl)silyllithium: Synthesis of tmeda or thf adducts of [Li{N(Ar)Si(SiMe3)3}] and 1,4-trimethylsilyl migration from oxygen to nitrogen

Reaction of ArN₃ (Ar = Ph, p-MeC₆H₄, 1-naphthyl) with [Li{Si(SiMe₃)₃}(thf)₃] yielded lithium amides [Li{N(Ar)Si(SiMe₃)₃}L] (L = tmeda or (thf)₂). Similar treatment of o-phenylene diazide with 2 equiv. of [Li{Si(SiMe₃)₃}(thf)₃] formed dilithium diamide complex 4. Reaction between o-Me₃SiOC₆H₄N₃ and [Li{Si(SiMe₃)₃}(thf)₃] afforded, via 1,4-trimethylsilyl migration from oxygen to nitrogen, [Li{OC₆H₄{N(SiMe₃)Si(SiMe₃)₃}-2}]₂ (5). The structures of complexes 3 and 5 have been determined by single crystal X-ray diffraction techniques.     

Erste Kristallstruktur eines Selenans; Metall(II)-Komplexe mit dem 2,4,6-Tris(trifluormethyl)selenophenolat-Liganden

The First Structure of a Selenane; Metal(II) Complexes with the 2,4,6-Tris(trifluoromethyl)-selenophenolato Ligand R_fSeH 1 is obtained in a single pot reaction of R_fLi [R_f = 2,4,6-tris(trifluoromethyl)phenyl] with elemental selenium and following treatment with HBF₄. 1 gave the first crystal structure of a selenane. Reaction of 1 with M[N(SiMe₃)₂]₂ (M = Zn, Pb) in the molar ratio of 2:1 yielded the metal selenophenolates Zn(SeR_f)₂ · HN(SiMe₃)₂ 2 and [Pb(SeR_f)₂]₂ 3. 2 crystallizes as hexamethyldisilazane adduct, 3 as a dimer.     

Two‐Coordinate Iron(I) Complex [Fe{N(SiMe3)2}2]−: Synthesis,Properties, and Redox Activity

First‐row two‐coordinate complexes are attracting much interest. Herein, we report the high‐yield isolation of the linear two‐coordinate iron(I) complex salt [K(L)][Fe{N(SiMe₃)₂}₂] (L=18‐crown‐6 or crypt‐222) through the reduction of either [Fe{N(SiMe₃)₂}₂] or its three‐coordinate phosphine adduct [Fe{N(SiMe₃)₂}₂(PCy₃)]. Detailed characterization is gained through X‐ray diffraction, variable‐temperature NMR spectroscopy, and magnetic susceptibility studies. One‐ and two‐electron oxidation through reaction with I₂ is further found to afford the corresponding iodo iron(II) and diiodo iron(III) complexes.     

Synthesis and reactivity of new trimethylplatinum(IV) complexes containing chiral Schiff bases as ligands: Crystal structure of (OC-6-44-C)-[PtIMe3{κ-(R)-Ph2P(C6H4)CHNC*H(Ph)Me-P,N}]

Reaction of the tetranuclear complex [PtIMe₃]₄ with the ligand (S)- and (R)-Ph₂P(C₆H₄)CHNC*H(Ph)Me in a 1:4 molar ratio yields the mononuclear neutral complexes in diastereoisomeric mixtures [PtIMe₃{κ²-Ph₂P(C₆H₄)CHNC*H(Ph)Me-P,N}]. Iodide abstraction from mixture with AgBF₄ in the presence of pyridine (Py) induces a reductive elimination reaction with loss of ethane, leading to the cationic complex [PtMe(Py){κ²-Ph₂P(C₆H₄)CHNC*H(Ph)Me-P,N}][BF₄] [C* = (S)-, 3; (R)-, 4]. When this reaction was carried out in the presence of PPh₃ a consecutive orthometallation reaction with loss of methane is produced, forming the cationic complex [Pt(PPh₃){κ³-Ph₂P(C₆H₄)CHNC*H(C₆H₄)Me-C,P,N}][BF₄], [(S)-, 5; (R)-, 6]. All species were characterised in solution by ¹H and ³¹P{¹H} NMR spectroscopy, elemental analysis and mass spectrometry.The crystal structure of the diastereoisomer (OC-6-44-C)-[PtIMe₃{κ²-(R)-Ph₂P(C₆H₄)CHNC*H(Ph)Me-P,N}] has been determined by single-crystal X-ray diffraction.     

Homoleptic Two‐Coordinate Silylamido Complexes of Chromium(I), Manganese(I), and Cobalt(I)

Anionic two‐coordinate complexes of first‐row transition‐metal(I) centres are rare molecules that are expected to reveal new magnetic properties and reactivity. Recently, we demonstrated that a N(SiMe₃)₂^? ligand set, which is unable to prevent dimerisation or extraneous ligand coordination at the +2 oxidation state of iron, was nonetheless able to stabilise anionic two‐coordinate Fe^I complexes even in the presence of a Lewis base. We now report analogous Cr^I and Co^I complexes with exclusively this amido ligand and the isolation of a [Mn^I{N(SiMe₃)₂}₂]₂^2? dimer that features a Mn?Mn bond. Additionally, by increasing the steric hindrance of the ligand set, the two‐coordinate complex [Mn^I{N(Dipp)(SiMe₃)}₂]^? was isolated (Dipp=2,6‐iPr₂‐C₆H₃). Characterisation of these compounds by using X‐ray crystallography, NMR spectroscopy, and magnetic susceptibility measurements is provided along with ligand‐field analysis based on CASSCF/NEVPT2 ab initio calculations.     

Versatile coordination chemistry of rhodium complexes containing the bis(trimethylsilylmethyl)tellane ligand

When RhCl₃ · 3H₂O was treated with an excess of Te(CH₂SiMe₃)_2, a mononuclear mer-[RhCl₃{Te(CH₂SiMe₃)₂}₃] (1) was observed as the main product. By reducing the metal-to-ligand molar ratio, dinuclear [Rh₂(μ-Cl)₂Cl₄{Te(CH₂SiMe₃)₂}₄] (2) was obtained in addition to 1. Further reduction of the metal-to-ligand ratio resulted in the formation of [Rh₂(μ-Cl)₂Cl₄(OHCH₂CH₃){Te(CH₂SiMe₃)₂}₃] (3). The treatment of mer-[RhCl₃(SMePh)₃] (4) with two equivalents of Te(CH₂SiMe₃)₂ affords a mixture of mer-[RhCl₃{Te(CH₂SiMe₃)₂}₃] (1) and mer-[RhCl₃{Te(CH₂SiMe₃)₂}₂(SMePh)] (5). All complexes 1-4 and 5 · ½EtOH were characterized by X-ray crystallography and ¹²⁵Te NMR spectroscopy, where appropriate. The definite assignment of the ¹²⁵Te chemical shifts enabled a plausible discussion of the assignment of some unknown resonances that were observed in the NMR spectra.