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Zur Addition von Übergangsmetallhalogeniden an Acetylacetonate zweiwertiger Metallionen (1992)

Döring, M. ; Görls, H. ; Uhlig, E. ; [et al.]

Weinheim : Wiley-Blackwell

Zeitschrift für anorganische Chemie 614 (1992), S. 65-72

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ISSN: 0044-2313

Keywords: Transition metal halides acetylacetonate complexes ; preparation ; crystal structure ; Chemistry ; Inorganic Chemistry

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology

Description / Table of Contents: Addition of Transition Metal Dihalides to Acetylacetonates of Divalent Metal IonsTransition metal dihalides aMIIX2 (FeCl2, CoCl2 NiBr2 etc.) are added by the chelates MII(acac)2 under formation of binuclear complexes (THF)2MII(acac)2(aMIIX2). The octahedral and the tetrahedral centre of these compounds are connected by tridentate oxygen atoms of the two acetylacetonato ligands which are simultaneously included in four-membered rings (MIIO2aMII). The addition is combined with a deformation of the octahedral centre, as a prerequisite of a closest package of the atoms within the MIIO2aMII-ring.In the trinuclear complex (THF)2Ni(acac)2(HgCl2)2 III the interaction between the three coordination centres is weak. No structural change of the octahedral centre (THF)2Ni(acac)2 is found, but the HgCl2-groups diverge slightly from linearity (Cl—Hg—Cl 171.1°).No binuclear complexes with a central ion of the oxidation state III in the octahedral centre were obtained. One reason is the lowered donor strength of the bidentate Lewis base function of the octahedral centre [(THF)2Mn+(acac)2]n-2 with M+3 as a centralatom. Reacting systems with di- and trivalent ions prefer ionic complexes, as it is shown by the formation of [(THF)2V(acac)2][(THF)CoCl3] IV from VCl3 and Co(acac)2.The crystal structures of (THF)2Co(acac)2CoCl2II and [(THF)2V(acac)2][(THF)CoCl3] IV were determined by x-ray diffraction. II: orthorhombic-primitive; space group P212121, Z = 4; a = 967.4(2), b = 1453.4(3), c = 1715.9(4) pm; R = 0.049 for 3084 observed reflections. IV: triclinic; space group P1, Nr. 2; Z = 2; a = 871,5(2), b = 930,6(3), c = 1865,6(6) pm; α = 101,70(2), b̃ = 92,45(2), γ = 91,06(2)°; R = 0,060 für 4221 observed reflections.

Notes: Bis(acetylacetonate) von Magnesium(II), Cobalt(II) oder Nickel(II) addieren Dihalogenide wie FeCl2, CoCl2 oder NiBr2 (aMIIX2) unter Bildung binuklearer Komplexe (THF)2MII(acac)2(aMIIX2), in denen ein oktaedrisches und ein tetraedrisches Zentrum über zwei dreibindige Sauerstoffatome der Acetylacetonatliganden miteinander verknüpft sind (Bildung eines viergliedrigen MIIO2aMII-Ringes). Die Addition ist mit einer Deformation des oktaedrischen Zentrums verbunden, die eine dichte Packung der vier Atome des MIIO2aMII-Ringes ermöglicht.Im trinuklearen Komplex (THF)2Ni(acac)2(HgCl2)2 III bleibt die Wechselwirkung zwischen den drei Koordinationszentren gering. Das oktaedrische Zentrum (THF)2Ni(acac)2 wird strukturell nicht verändert, allerdings weichen die beiden HgCl2-Bausteine (Valenzwinkel 171,1°) von der Linearität ab.Es gelang nicht, binukleare Komplexe mit einem Zentralatom der Oxidationsstufe III im oktaedrischen Zentrum darzustellen. Ein Grund dafür ist die verringerte Donorstärke der zweizähligen Lewisbasen-Funktion im oktaedrischen Zentrum [(THF)Mn+(acac)2]n-2 für M+3 als Zentralion. Reaktive Systeme mit zwei- und dreiwertigen Kationen weichen auf die Seite von ionischen Komplexen aus, wie die Bildung von [(THF)2V(acac)2][(THF)CoCl3] IV aus VCl3 und Co(acac)2 zeigt.Die Kristallstrukturen von (THF)2Co(acac)2CoCl2 II und [(THF)2V(acac)2][(THF)CoCl3] IV wurden durch Röntgenbeugung bestimmt.II: orthorhombisch primitiv, Raumgruppe P212121, Z = 4; a = 967,4(2), b = 1453,4(3), c = 1715,9(4) pm; R = 0,049 für 3084 beobachtete Reflexe.IV: triklin, Raumgruppe P1, Nr.2; Z = 2; a = 871,5(2), b = 930,6(3), c = 1865,6(6) pm; α = 101,70(2), b̃ = 92,45(2), γ = 91,06(2)°; R = 0,060 für 4221 beobachtete Reflexe.

Additional Material: 4 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/zaac.19926140813

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The electro-osmotic actuation of implantable insulin micropumps (1983)

Uhlig, E. L. P. ; Graydon, W. F. ; Zingg, W.

Hoboken, NJ : Wiley-Blackwell

Journal of Biomedical Materials Research 17 (1983), S. 931-943

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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.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/jbm.820170605

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Struktur und thermischer Abbau von Bis (1,3-diketonato) cobalt-bisimidazolenHerrn Professor Wolfgang Beck zum 60. Geburtstage am 5. Mai 1992 gewidmet (1992)

Döring, M. ; Ludwig, W. ; Uhlig, E. ; [et al.]

Weinheim : Wiley-Blackwell

Zeitschrift für anorganische Chemie 611 (1992), S. 61-67

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ISSN: 0044-2313

Keywords: Bis(1, 3-diketonato)cobalt-bisimidazoles ; crystal structure ; thermal degradation ; Chemistry ; Inorganic Chemistry

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology

Description / Table of Contents: Structure and Thermal Degradation of Bis(1,3-diketonato)cobaltbisimidazolesThe crystal structure of Co(bzac)2(HIm)2. 2MeOH (I) and Co(acac)2(HIm)2 (II) were determined by x-ray diffraction. II: triclinic, space group P1, Z = 2, a = 746.3(1), b = 948.2(1), c = 1396.7(2)pm, α = 85.18(1)°, β = 88.96(1)°, γ = 80.72(1)°, R = 3.0% for a total of 2194 observed reflections. I: monoclinic, P21/c, Z = 2, a = 964.2(3), b = 864.5(2), c = 1769.8(4)pm, β = 98.87(2)°, R = 4.7% for a total of 967 observed reflections. In both compounds centrosymmetric molecules with two bidentate diketonato groups and two imidazole ligands in trans-position are present. The molecules of II are linked by N—H…O-bridges within layers, while in the lattice of I by the interaction with methanol molecules N-H…O-H…O-bridges are formed.The nature of the H-bridges is the deciding factor for the first step of the thermal degradation of the complexes. The N-H…O-bridges of II relieves the change of the acidic protons of the imidazole to the acetylacetonato ligands. Therefore in the first step acetylacetone is eliminated. No such bridges are present in the complex I. Therefore, in the first step, imidazole and methanol are removed. On heating in O-donor solvents the reaction of I is quite analogous, and this is the reason for the application of this complex as a latent initiator of the epoxide polymerisation.

Notes: Die Kristallstrukturen von Co(bzac)2(HIm)2 · 2MeOH (I) und Co(acac)2(HIm)2 (II) wurden durch Röntgenbeugung bestimmt. II: triklin, Raumgruppe P1, Z = 2, a = 746,3(1), b = 948,2(1) c = 1396,7(2)pm, α = 85,18(1)°, β = 88,96(1)°, γ = 80, 72(1)°, R = 3,0% fur 2194 beobachtete Reflexe; I: monoklin, P21/c, Z = 2, a = 964,2(3), b = 864,5(2), c = 1769,8(4)pm, β = 98,87(2)°, R = 4,7% für 967 Reflexe. In beiden Verbindungen liegen zentrosymmetrische Moleküle vor mit jeweils zwei chelatartig gebundenen Diketonatgruppen und zwei transständigen Imidazol-Liganden. Bei II sind die Moleküle über N—H…O-Brücken zu Schichten miteinander verknüpft, während bei I eine Verkettung über die Methanol-Moleküle mit N—H…O…H…O-Brücken vorliegt. Die Art der H-Brücken ist maßgebend für den ersten Schritt des thermischen Abbaus der Komplexe. Die N—H…O-Brücken von II erleichtern den Übergang der aciden Protonen der Imidazol- auf die Acetylacetonatoliganden. Im ersten Schritt wird daher Acetylaceton abgespalten. Dem Komplex I fehlen solche Brücken, deshalb werden im ersten Schritt Imidazol und Methanol eliminiert. Ganz analog verhält sich I beim Erhitzen in O-Donatorlösungsmitteln (Alkohole, Epoxide). I ist daher als latenter Initiator fur die Polymerisierung von Epoxiden geeignet.

Additional Material: 5 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/zaac.19926110510

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