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  • Articles  (3)
  • Articles: DFG German National Licenses  (3)
  • 1,3-Diketonate imidazole complexes of cobalt, nickel, copper  (1)
  • Polymer and Materials Science  (1)
  • Thermochemistry  (1)
  • binuclear complexes  (1)
  • Wiley-Blackwell  (3)
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  • Articles  (3)
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  • Articles: DFG German National Licenses  (3)
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  • Wiley-Blackwell  (3)
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  • 1
    ISSN: 0044-2313
    Keywords: 1,3-Diketonate imidazole complexes of cobalt, nickel, copper ; Thermochemistry ; Chemistry ; Inorganic Chemistry
    Source: Wiley InterScience Backfile Collection 1832-2000
    Topics: Chemistry and Pharmacology
    Description / Table of Contents: NH-acidic Behaviour of Imidazole in the Course of the Thermal Degradation of its Bis(adducts) with Transition Metal 1,3-DiketonatesThe behaviour of complexes of the type M(O—O)2(HIm)2 (O—O = 1,3-diketonate, HIm = imidazole, M = Co, Ni, Cu) in the course of the thermal degradation is different. In the case of M(acac)2(HIm)2 in the first step acetylacetone is split off. By proton transfer from imidazole to the acetylacetonato ligands the bis(imidazolates) M(Im)2 are formed, which, at higher temperatures eliminate both imidazolyl residues, probably as 1H, 1H′-(2,2′)-bisimidazolyl.The thermal degradation of M(bzac)2(HIm)2 or M(dbm)2(HIm)2 (Hbzac = benzoylacetone, Hdbm dibenzoylmethane) starts with the partial elimination of imidazole. The intermediates M(bzac)(Im) or M(dbm)(Im) are obtained, and the final product of thermal degradation is the metal oxide.The main reasons for the different thermal behaviour of the complexes M(O—O)2(HIm)2 are differences in the volatility of the 1,3-diketones and probably in the molecular structures.
    Notes: Komplexe des Typs M(O—O)2(HIm)2 (O—O = 1,3-Diketonat; HIm = Imidazol; M = Co, Ni, Cu) zeigen beim thermischen Abbau ein differenziertes Verhalten. Im Falle von M(acac)2(HIm)2 wird in den ersten Stufen Acetylaceton abgespalten. Unter Protonenübertragung von Imidazol auf die Acetylacetonat-Liganden entstehen Bis-Imidazolate M(Im)2, die bei höherer Temperatur die Imidazolylreste wahrscheinlich als 1H, ′H-(2,2′)-Bisimidazolyl eliminieren.Der thermische Abbau von M(bzac)2(HIm)2 bzw. M(dbm)2(HIm)2 (Hbzac = Benzoylaceton, Hdbm = Dibenzoylmethan) beginnt mit der partiellen Abspaltung von Imidazol. Es wird ein Zwischenprodukt der Zusammensetzung M(bzac)(Im) bzw. M(dbm)(Im) erhalten. Anorganisches Endprodukt des Abbaus ist das Metalloxid.Wesentliche Gründe für das differenzierte Verhalten der Komplexe des Typs M(O—O)(HIm)2 beim thermischen Abbau werden in der unterschiedlichen Flüchtigkeit der 1,3-Diketone und in Strukturunterschieden gesehen.
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  • 2
    Electronic Resource
    Electronic Resource
    Weinheim : Wiley-Blackwell
    Zeitschrift für anorganische Chemie 619 (1993), S. 753-760 
    ISSN: 0044-2313
    Keywords: Metal bis(acetylacetonate) complexes ; binuclear complexes ; ligand exchange reactions ; crystal structure ; Chemistry ; Inorganic Chemistry
    Source: Wiley InterScience Backfile Collection 1832-2000
    Topics: Chemistry and Pharmacology
    Description / Table of Contents: Exchange of Metal Ions in the System Acetylacetonate/Halide/Tetrahydrofuran.As bifunctional Lewis bases metal bis(acetyl-acetonates) react with zinc(II) chloride under formation of binuclear complexes (THF)2M(acac)2ZnCl2 (M = Ni, Co, Mg). The octahedral and the tetrahedral centre of these compounds are connected by tridentate oxygen atoms of the two acetylacetonato ligands which are simultaneously part of a four-membered ring MOZnO. The addition is combined with a deformation of the octahedral centre, as a prerequisite of a closest package of the atoms within the MOZnO ring.With mercury(II) chloride the metal bis(acetylacetonates) react as tetrafunctional Lewis bases. In the trinuclear complexes (THF)2M(acac)2(HgCl2)2 (M = Co, Ni, Mg) the interaction between the three coordination centres is weak. No structural change of the octahedral centre (THF)2M(acac)2 is found, but the HgCl2 group diverge slightly from linearity.A ligand exchange was observed in the following cases: (a)Reaction of vanadium(III) chloride with Co(acac)2 under formation of [(THF)2V(acac)2][(THF)CoCl3] (transition of the acetylacetonato ligands to the higher valent central atom).(b)Reaction of magnesium halides with M(acac)2 and formation of (THF)3Mg(acac)2MX2(c)Formation von (THF)3Co(acac)(μ - C1)ZnC12 (V) by the reaction of Zn(acac)2 with cobalt(l1) chlorideIn the complex V the octahedral ccntrc of cobalt(II) is connected with the tetrahedral centre of zinc(I1) by tridentate oxygen atom of the acetylacetonato ligand and a chloro bridge (formation of the four-membered CoClZnO cycle with a closest package of the atoms).A driving force for reaction c is the formation of the stable tetrahedral OZnCI3 group. Important for the li- gand exchange according to c is the stability of the octa- hcdral MgO6 moiety and the easy formation of the tetra- hedral MO2X2 group with a transition metal ion.(THF)3Co(acac)(μ-CI)(HgCl2) (VI) is isoslruclural with V. But there is a marked diffcrence between the bond angles of the tetrahedral central atom including the termi- nal chloro ligands (120.7° for V; 143.7° for VI).The crystal structure of (THF)3Co(acac)(μ-CI)ZnCl2 (V) was determined by X-ray diffraction: monoclinic; space group P2,/n; Z = 4; a = 1 177.4(5); b = 1628.9(4); c = 1284.2(6) pm; β = 99.54(4)°; R = 6.71 % for 2160 observed reflections.
    Notes: Metall-bis(acetylacetonate) fungieren in THF gegenüber Zink(II)-chlorid als bifunktionelle Lewis-Basen und bilden binukleare Komplexe (THF)2M(acac)2ZnCl2 (M = Co, Ni, Mg). Ein oktaedrisches und ein tetraedrisches Zentrum sind über zwei dreibindige Sauerstoffatome der Acetylacetonatliganden miteinander verknüpft (Bildung eines viergliedrigen MOZnO-Rings). Die Addition ist mit einer Deformation des oktaedrischen Zentrums verbunden, die eine dichte Packung der vier Atome des MOZnO-Ringes ermöglicht.Gegenüber Quecksilber(II)-chlorid fungieren die Metall-bis(acetylacetonate) als tetrafunktionelle Lewis-Basen. In den trinuklearen Komplexen (THF)2M(acac)2(HgCl2)2 (M = Co, Ni, Mg) bleibt die Wechselwirkung zwischen den drei Koordinationszentren gering; das oktaedrische Zentrum wird strukturell nicht verändert, die beiden HgCl2-Bausteine weichen nur gering von der Linearität ab.Ein Ligandenaustausch wurde in folgenden Fällen beobachtet: (a)Umsetzung von Vanadium(III)-chlorid mit Co(acac)2 unter Bildung von [(THF)2V(acac)2][(THF)CoCl3] (übergang der Acetylacetonatliganden auf das höherwertige Zentralatom).(b)Umsetzung von Magnesiumhalogeniden mit M(acac)2 unter Bildung von (THF)2Mg(acac)2MX2(c)Bildung von (THF)3Co(acac) (μ - Cl)ZnCl2 (V) aus Zn(acac)2 und Cobalt(II)-chloridIm Komplex V ist das oktaedrische Zentrum am Cobalt über ein dreibindiges Sauerstoffatom des Acetylacetonatoliganden und eine Chlorobrücke mit dem tetraedrischen Zentrum am Zink verknüpft (Bildung eines viergliedrigen CoClZnO-Ringes mit dichtester Packung der Atome).Wesentliche Triebkraft für die Umsetzung gemäß c ist die Bildung der stabilen OZnCl3-Gruppierung. Für den Ligandenaustausch gemäß b ist die Stabilität der oktaedrischen MgO6-Gruppierung und die leichte Bildung der teraedrischen Baugruppe MO2X2 bei den übergangsmetallen maßgebend. (THF)3Co(acac)(μ - Cl)HgCl2 (VI) ist isostrukturell mit V. Deutlich verschieden sind allerdings die Valenzwinkel am tetraedrischen Zentralatom, in die die terminalen Chloroliganden einbezogen sind (120,7° für V; 143,7° für VI).Die Kristallstruktur von (THF)3Co(acac)(μ - Cl)ZnCl2 (V) wurde durch Röntgenbeugung bestimmt: monoklin, Raumgruppe P21/n, Z = 4; a = 1 177,4(5); b = 1 628,9(4); c = 1 284,2(6) pm; β = 99,54(4)°; R = 6,71% für 2 160 beobachtete Reflexe.
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  • 3
    Electronic Resource
    Electronic Resource
    Hoboken, NJ : Wiley-Blackwell
    Journal of Biomedical Materials Research 17 (1983), S. 931-943 
    ISSN: 0021-9304
    Keywords: Chemistry ; Polymer and Materials Science
    Source: Wiley InterScience Backfile Collection 1832-2000
    Topics: Medicine , Technology
    Notes: A study using an electro-osmotic cell suitable for actuating an implantable insulin micropump showed that controlled variable flow rates in the order of 0.2 mL/day are possible. The cell functioned continuously with low energy and power requirements and long service life. The principle of operation is compatible with achieving the very low flow rates necessary if highly concentrated insulin is to be used to avoid frequent insulin reservoir refilling. An electro-osmotic cell, Ag/ AgCl/NaCl(aq)/ cation exchange membrane/NaCl(aq)/ AgCl/ Ag, was connected to a constant current power supply which reversed the direction of the current every 10 mins causing a to-and-fro transport of fluid through the membrane. Flow rates of 0.15-0.60 μL/min were achieved with currents of 2.5-10 mA. At the low flow rate, energy consumption was 6.4 × 10-2 J/μL and peak power requirement was 〈2.0 × 10-4 W. Fluid was transported against a pressure gradient of 52 cm Hg. The cell contained a total electrolyte volume of 〈0.25 mL. The membrane showed no change in properties after 10,000 current reversals (69 days). To function as an actuator for an implantable insulin micropump, the electro-osmotic cell requires a switching and valving assembly; a suitable design for this is briefly considered.
    Additional Material: 5 Ill.
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