Azulen als Brückenligand in Zweikernigen Paramagnetischen Nickelkomplexen — Synthese und Eigenschaften

Azulene as Bridging Ligand in Dinuclear Paramagnetic Complexes of Nickel — Synthesis and Spectroscopic Properties The reactivity of dianions of several alkyl substituted azulene derivates towards half sandwich complexes [(η⁵‐C₅R_1‐5)Ni (η²‐acetylacetonat)] (R = H, Me, Ethyl) has been studied and leads to the formation of paramagnetic dinickel complexes of the nonbenzenoid hydrocarbon azulene. From these studies it is found that the five membered ring system of the azulene ligand is coordinated in a nickelocene like fashion, the seven membered ring system in a halfopen metallocene type fashion. Therein the seven membered azulene ring unit is complexed in a pentadienyllike fashion. This corresponds to cyclovoltammetric studies in which a correlation with the potentials for alkylated nickelocene derivatives is found.     

1,1-Dithiooxalsäurederivate als Liganden in Übergangsmetallkomplexen: Struktur von O-Methyl-1,1-dithiooxalato-bis(triphenylphosphin)kupfer(I) und -silber(I)

1,1-Dithiooxalic Acid Derivatives as Ligands in Transition Metal Complexes: Structure of O-Methyl-1,1-dithiooxalato-bis(triphenylphosphine)copper(I) and silver(I) Despite O-Alkyl-1,1-dithiooxalates are also tetradentate thioligands their tendency towards the formation of multi-nuclear bridged chelates as found for the basic 1,1-dithiooxalate does practically not exist because of derivatisation. The reaction with triphenylposphinemetal(I)-halogenides yields defined mono-nuclear mixed ligand complexes: O-Methyl-1,1-dithiooxalato-bis(triphenylphosphine)copper(I) ( 2 ) and silver(I) ( 1 ). X-ray analysis shows that both complexes ( 1 and 2 ) are isostructural and crystallize in the monoclinic space group P2₁/n: (Ph₃P)₂Ag(S₂C₂O₂Me) ( 1 ) with a = 12.794(1), b = 21.314(4), c = 13.560(1) Å, β = 97.983(6)°, and (Ph₃P)₂Cu(S₂C₂O₂Me) ( 2 ) with a = 12.622(1), b = 21.196(2), c = 13.426(1) Å, β = 96.533(7)°. These complexes are the first authentic examples of exclusively end-on coordinated thiooxalate.     

Trithiooxalat als variabler Brückenligand – Kristall- und Molekülstruktur von μ-Trithiooxalato-bis[bis(triphenylphosphan)kupfer(I)]

Trithiooxalate as Varying Bridging Ligand – Crystal and Molecular Structure of μ-Trithiooxalato-bis[bis(triphenylphosphane)copper(I)] Due to its design, trithiooxalat (trto) as a multidentate, chalcogen-rich ligand allows different coordination possibilities. In contrast to the corresponding dinuclear silver complex [(Ph₃P)₂Ag]₂(trto), which is side-on(S,S′)/end-on(S′,S″) coordinated, the title complex is exclusively side-on (S,S′ and S″,O) coordinated involving the oxygen donor atom. [(Ph₃P)₂Cu]₂(trto) crystallizes in the triclinic space group P1 (No. 2) with a = 10.195(2), b = 13.090(3), c = 13.450(3) Å, α = 116.10(2)º, β = 90.10(2)º, γ = 101.49(2)º, and Z = 1. The bridging ligand with its nonsymmetrical donor atom set is disordered around the centre of symmetry (inversion centre).     

Vibrational frequencies and structural determinations of 1,1-dicyanocyclopropane

The vibrational frequencies and corresponding normal mode assignments of 1,1-dicyanocyclopropane are examined theoretically using the Gaussian98 set of quantum chemistry codes. All normal modes were successfully assigned to one nine types of motion predicted by a group theoretical analysis (C-H stretch, C[triple bond]N stretch, C-C stretch, C-C[triple bond]N bend, C-C-C bend, CH2 scissors, CH2 wag, CH2 rock, CH2 twist) utilizing the C2v symmetry of the molecule. The molecular orbitals of 1,1-dicyanocyclopropane are also examined.     

Umsetzungen von Ferrocenol und 1,1′-Ferrocendiol mit Cyclotriphosphazenen,P3N3F6 und P3N3Cl6

Reactions of Ferrocenol and 1,1′-Ferrocendiol with Cyclotriphosphazenes, P₃N₃F₆ and P₃N₃Cl₆ The hexahalogeno-cyclotriphosphazenes, P₃N₃X₆ (X ? F ( 1 a ), Cl ( 1 b )), react with ferrocenol (FcOH) in a molar ratio 1 : 1 to give the ferrocenoxy derivatives, FcO[P₃N₃X₅] (X ? F ( 3 a ), Cl ( 3 b )); in an analogous manner the tetrameric ring P₄N₄Cl₈ ( 2 b ) is converted to FcO[P₄N₄Cl₇] ( 4 b ).

1 Abkürzungen: Fc = Ferrocenyl, (C₅H₅)Fe(C₅H_4?); fc = 1,1′-ferrocendiyl, Fe(C₅H_4?)₂; rc = 1,1′-ruthenocendiyl, Ru(C₅H_4?)₂. Fluorphosphazene werden mit a , Chlorphosphazene mit b gekennzeichnet.

With 1,1′-ferrocenediol, (fc(OH) ₂ ), the cyclo triphosphazenes react in a molar ratio 1 : 1 to produce fcO ₂ [P ₃ N ₃ X ₄ ] (X ? F ( 5 a ), Cl ( 5 b )). According to the x-ray structure analysis, the 1,1′-ferrocenediolato group in 5 a , b is bound to two different phosphorus atoms. On the contrary, the 1,1′-ferrocenedithiolato- and 1,1′-ferrocenediselenolato units in fcS ₂ [P ₃ N ₃ X ₅ ] (X ? F ( 6 a ), Cl ( 6 b )) and fcSe ₂ [P ₃ N ₃ X ₅ ] (X ? F ( 7 a ), Cl ( 7 b )) are attached to only one phosphorus atom, and spirocyclic 1,3-dichalcogena-2-phospha-[3]ferrocenophanes are formed. All new products have been characterized on the basis of their ¹ H, ¹³ C and ³¹ P NMR as well as EI mass spectra. The molecular structures of 5 a , b and 6 a have been determined by x-ray structure analyses.     

Nickel(I)‐Komplexe mit 1,1′‐Bis(phosphino)ferrocenen als Liganden

Nickel(I) Complexes with 1,1′‐Bis(phosphino)ferrocenes as Ligands The thermically stable monomeric Nickel(I) complexes [(d^tbpf)Ni(acac)] ( 1 ) and [(dⁱppf)NiCl] ( 2 ) were synthesized and characterized by elemental analyses, EPR spectroscopy, and by X‐ray crystal structure analyses of single crystals (d^tbpf: 1,1′‐bis(di‐tertbutylphosphino)ferrocene; dⁱppf: 1,1′‐bis(diisopropylphosphino)ferrocene). 1 is formed by reduction of Ni(acac)₂ with triethylaluminium in the presence of d^tbpf, together with the nickel(0) complex [(d^tbpf)Ni(C₂H₄)]. 1 contains a Ni^I atom surrounded of two O‐ and two P donor atoms in a distorted tetrahedral coordination. 2 was obtained by reduction of [(dⁱppf)NiCl₂] with NaBH₄. In 2 the nickel(I) atom adopts trigonal planar coordination.