Darstellung und Strukturanalyse neuer Komplexe von Eisen(II), Cobalt(II) und Nickel(II) nach synergistischer Extraktion

Zusammenfassung Die synergistische Extraktion von Eisen(II)-, Cobalt(II)- und Nickel(II)-Komplexen wird untersucht. Verwendet werden fluorierte Diketone (A) (Derivate des Thenoyltrifluoracetons) und eine neue Gruppe Schiff' scher Basen. Aus den Extraktionskurven nach der Job- und Molar-Ratio-Methode, der Elementaranalyse und aus Molmassenbestimmungen werden Komplexverbindungen der Zusammensetzung [M₄A₈B⁴] nachgewiesen. Aus den Elektronen- und IR-Spektren und aus magnetischen Messungen wird für die Ni(II)-Komplexe eine octaedrische Struktur vorgeschlagen.

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Preparation and structure analysis of new iron(II), cobalt(II) and nickel(II) complexes by synergistic extraction

Summary The synergistic extraction of iron(II), cobalt(II) and nickel(II) complexes was investigated. Fluorinated diketones (A) (derivates of thenoyltrifluoracetones) and a new group of Schiff bases were used. By Job and molar-ratio method investigation on the extraction curves, by elementary analysis and molar mass detection, complex compounds of the composition [M₄A₈B⁴] could be proved. Electron and infrared spectra and magnetical measurements led to an octahedral structure proposal for the Ni(II)-complexes.

Mein Dank gilt besonders Herrn Professor Dr. H. Specker, Direktor des Instituts für Anorganische Chemie I der RUB, für die Zurverfügungstellung der Geräte und Chemikalien, Herrn Professor Dr. Metfessel und Frau Dr. Magdela Gronau für die magnetischen Messungen in der Abteilung Physik der RUB.     

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.     

Binukleare Nickel(II)‐Komplexe mit Oxalamidinaten als Brückenliganden: Synthese und Strukturen von Verbindungen mit planarer,tetraedrischer, tetragonal‐pyramidaler und oktaedrischer Koordination

Binuclear Nickel(II) Complexes with Oxalamidinates as Bridging Ligands: Synthesis and Struktures of Compounds with Planar, Tetrahedral, Tetragonal‐pyramidal, and Octahedral Coordination Oxalamidines R¹–NH–C(=NR²–C(=NR²)–NH–R¹ react selectively with Ni(acac)₂ under formation of the planar complexes [(acac)Ni(oxalamidinate)Ni(acac)]. Two crystal structures of the binuclear complexes with R = R′ = Ph ( 1 ) or p‐tolyl ( 2 ) show that the bridging oxalamidinates bind as bidendate ligands at each Nickel(II) atom. In contrast, the more sterically demanding fragment (Ph₃P)NiBr can only coordinate at sterically less demanding oxalamidinates to form complexes of the type [(Ph₃P)NiBr]₂(oxalamidinate) with tetrahedral coordination of Ni^II found by X‐ray analyses. Oxalamidines containing additional donor atoms in the side arms react very different, but in each case under formation of binuclear complexes, such as [(acac)₂Ni]₂( H₂E ) ( 8 ) (with R¹: –(CH₂)₃PPh₂, R²: p‐tolyl) in which the oxalamidine acts as bidentate neutral P,N‐ligand and the Ni^II atom has an octahedral environment. H₂F (with R¹: –(CH₂)₃PPh₂, R²: Mesityl), however, yields the planar complex [(acac)Ni]₂( F ) ( 9 ) with dianionic oxalamidinate under elimination of acetylacetone. There is no coordination of the donor groups of the side arms in the solid state of complex 9 , in contrast to the analogous binuclear complex [(acac)Ni]₂( H ) 10 (R¹: –CH₂–CH₂‐2‐pyridyl, R²: Mesityl). In this complex a distorted tetragonal‐pyramidal coordination of Ni^II is achieved. 2 reacts with an excess of LiCH₃ under elimination of the oxalamidinate to form the cluster compound Li₄(THF)₄Ni₂Me₈ in very good yields, while 9 yields the THF poorer cluster Li₂(THF)₂Li₂Ni₂Me₈ under similar conditions.     

Palladium(II)‐ und Platin(II)‐Komplexe mit dem Antimalariamittel Mefloquin als Liganden

Metal Complexes of Biologically Important Ligands. CXXVI. Palladium(II) and Platinum(II) Complexes with the Antimalarial Drug Mefloquine as Ligand The coordination sites of the antimalarial drug mefloquine (L) were studied. Reactions of the chloro bridged complexes (allyl)Pd(μ‐Cl)₂Pd(allyl) and (R₃P)(Cl)M(μ‐Cl)₂M(Cl)(PR₃) (M = Pd, Pt) with racemic mefloquine give the compounds (allyl)(Cl)Pd(L) ( 1 ), Cl₂(Et₃P)Pt(L) ( 2 ) and Cl₂(Et₃P)Pd(L) ( 3 ) with coordination of the piperidine N atom of mefloquine. In the presence of NaOMe the N,O‐chelate complexes Cl(Et₃P)Pt(L–H⁺) ( 4 ) and Cl(R₃P)Pd(L–H⁺) ( 5 , 6 , R = Et, nBu) were obtained. Protection of the piperidine N atom of mefloquine by protonation allows the synthesis of the complexes Cl₂(Et₃P)Pt(L + H⁺) ( 7 ) in which mefloquine is coordinated via the quinoline N atom. The structures of 2 , 3 and 4 were determined by X‐ray diffraction analysis. In the crystal of 4 pairs of enantiomers are found which are linked by two hydrogen bridges between the amine group and the chloro ligand.     

Polyol‐Metall‐Komplexe. 491) μ‐Dulcitolato‐O2, 3;4, 5‐Komplexe mit Amin‐Kupfer(II)‐ und ‐Nickel(II)‐Metallfragmenten

Polyol Metal Complexes. 49¹⁾ μ‐Dulcitolato‐O^{2, 3;4, 5} Complexes with Cu^II(en) and Ni^II(tren) Metal Fragments The dinuclear ethylenediamine‐copper(II) complex of the tetra‐anion of the achiral alditol dulcitol (galactitol) is remarkable, since it was the first crystalline carbohydrate—metal complex ever reported (W. Traube, G. Glaubitt, V. Schenck, Ber. Dtsch. Chem. Ges. 1930 , 63, 2083—2093). Although its existence is recognized for many decades, its structure remained unknown due to a kind of crystal packing that promotes twinning. Crystal growth at low temperatures now yielded crystalline specimens of [(en)₂Cu₂(Dulc2, 3, 4, 5H_—4)] · 7 H₂O ( 1 ) that have allowed us to unravel both the crystal structure and the twinning law. Closely related molecular structures are adopted by [(tren)₂Ni₂(Dulc2, 3, 4, 5H_—4)] · 20 H₂O ( 2 ) and [(Me₃tren)₂Ni₂(Dulc2, 3, 4, 5H_—4)] · 16 H₂O ( 3 ), the latter showing the shortest hydrogen bond towards a polyolate acceptor ever found (O···O distance: 2.422Å).     

Darstellung und spektroskopische Charakterisierung von Kupfer(II)- und Nickel(II)-tricyanmethanid-Komplexen mit Imidazol-Derivaten – Kristallstruktur von [Cu{C(CN)3}2(2-meiz)2]

Synthesis and Spectroscopic Characterization of Copper(II) and Nickel(II) Tricyanomethanide Complexes with Imidazoles – Crystal Structure of [Cu{C(CN)₃}₂(2-meiz)₂] The copper(II) and nickel(II) tricyanomethanide complexes with imidazoles of the type [Cu{C(CN)₃}₂L₄], [L = 2- or 4-methylimidazole (meiz)] and [M{C(CN)₃}₂L₂] [M = Cu, L = imidazole (iz), 2- or 4-meiz; M = Ni, L = iz, 2- or 4-meiz] were prepared and characterized by electronic, infrared, and – some of them – by ESR spectroscopy. The structure [Cu{C(CN)₃}₂(2-meiz)₂], solved by X-ray crystallographic analysis, shows a two-dimensional network with unsymmetric C(CN)₃-bridges between the Cu^II atoms. Polymeric structures with bridging C(CN)₃-groups were identified by means of spectroscopic methods also for the other [M{C(CN)₃}₂L₂] complexes. On the other hand, for the complexes [M{C(CN)₃}₂L₄] follow molecular structures, in which monodentate C(CN)₃ ligands are present. All compounds under investigation show a tetragonal-bipyramidal geometry with various degree of tetragonal distortion.     

Ringschlussreaktionen von 1-(2-Aminophenyl)-1-phenyl-äthylenen durch Kondensation mit Phosgen

Cyclization of 1-(2-aminophenyl)-1-phenyl-ethylenes or 1-(2-aminophenyl)-1-phenyl-propenes (II) by condensation with phosgene led to 4-phenyl-carbostyrils (III) or 2-chloro-4-phenyl-quinolines (IV). Similarly, thiophosgene afforded 4-phenyl-thiocarbostyril. Treatment of 1-(2-aminophenyl)-2-methyl-1-p-tolyl-propene (VII) with phosgene led to the corresponding isocyanate IX, which cyclized in the presence of aluminum chloride with loss of a methyl group to 3-methyl-4-p-tolyl-carbostyril (III-6). However, 1-(2-aminophenyl)-2-methyl-1-phenyl-propene (VIII) treated with phosgene gave the isocyanate XI and 3-phenyl-3-isopropenyloxindole (X). Cyclization of the isocyanate XI with aluminium chloride led simultaneously to 3-methyl-4-phenyl-carbostyril (XIV), and with migration of a methyl group to 3-methylene-4-methyl-4-phenyl-3. 4-dihydro-carbostyril (XV).     

Niederdruck-Oligomerisation von Mono-Olefinen mit löslichen Nickel/Aluminium-Bimetallkatalysatoren,Teil I Entwicklung neuer Katalysatorsysteme auf der Basis von π-Cyclobutadien-Nickel(II)-Verbindungen

Mixtures of π-tetramethylcyclobutadiene-nickeldihalides and LEWIS acids such as alkylaluminiumhalides in organic solvents represent new highly active homogeneous catalysts for the dimerization of ethylen, propene and butene under mild conditions. As a cocatalyst LEWIS bases may be used, in particular those containing trivalent phosphorous.     

Produktion von β-Lactamantibiotika durch Mikroorganismen

β-lactam antibiotics are commercially and clinically important compounds that are produced by bacteria as well as by filamentous fungi. There is a great interest not only to increase the yield of microbial antibiotic production but also to generate new and highly effective antibiotics. It may be foreseen that this aim is reached by the use of in vitro recombinant technology. The biochemical as well as the physiological data which seem to be important for the understanding of β-lactam biosynthesis is filamentous fungi are summarised. In addition, recent technical advances are mentioned which become available through molecular biology. Examples are given to demonstrate the feasability of DNA recombinant technology for biotcchnical applications by introducing novel biosynthetic pathways into fungal β-lactam producers.