W2Cl7(CCl), a Polymeric Tungsten Chlorocarbyne Complex

Black crystals of W₂Cl₇(CCl) were obtained from the reaction of WCl₆ and As in CCl₄ at 250 °C under solvothermal conditions. The crystal structure (orthorhombic, space group Pbca, a = 1196(1), b = 1215.6(7), c = 1584(1) pm, Z = 8) is built of infinite zig‐zag chains of dinuclear complexes connected via bridging Cl atoms. The individual complexes are face‐sharing double octahedra concatenated via bridging Cl ligands. Each W atom is in a distorted octahedral coordination environment of five Cl atoms an the carbon atom of the μ₂ bridging chloromethylidyne ligand leading to the formula [{Cl₂W(μ‐CCl)(μ₂‐Cl)₂WCl₂}(μ‐Cl)]_n. The short W‐W distance of 256 pm indicates a multiple W‐W bond, the W‐C bonds of 195 pm are in the typical range for μ₂‐alkylidyne ligands, the C‐Cl bond of 167 pm is consistent with a sp¹ hybridisation on the carbon atom.     

Dicarboxylatgruppen als Liganden und Anionen in Aquamagnesiumkomplexen: Kristallstrukturen von [Mg (C4H2O4)(H2O)4] · H2O und [Mg(H2O)6](C4HO4)2 · 2H2O ((C4H2O4)2— = Fumarat; (C4HO4)— = Hydrogenacetylendicarboxylat)

Dicarboxylate Groups as Ligands and Anions in Aquamagnesium Complexes: Crystal Structures of [Mg (C₄H₂O₄)(H₂O)₄] · H₂O and [Mg(H₂O)₆](C₄HO₄)₂ · 2H₂O ((C₄H₂O₄)^2— = Fumarate; (C₄HO₄)^— = Hydrogenacetylenedicarboxylate) Crystals of tetraaqua(fumarato)magnesium‐hydrate ( 1 ) and hexaaquamagnesium‐bis(hydrogenacetylenedicarboxylate)‐dihydrate ( 2 ) were prepared by reacting MgCl₂ with sodium fumarate and acetylenedicarboxylic acid, respectively. In 1 cis‐Mg(H₂O)₄ units are bridged by α, Ö‐bonded fumarate groups. The resulting zig zag chains exhibit the maximum symmetry compatible with space group symmetry C2/c. 2 consists of layers of voluminous [Mg(H₂O)₆]²⁺ cations alternating with layers of C₄HO₄^— anions. The nearly planar anions are held together by parallel stacking and by short hydrogen bonds. Both structures contain efficient H bridging systems. 1 : Space group C2/c, Z = 4, lattice constants at 20 °C: a = 5.298(1), b = 13.178(2), c = 13.374(2)Å; ß = 94.79(2)°, R₁ = 0.024. 2 : Space group P1, Z = 1, lattice constants at 20 °C: a = 5.985(1), b = 6.515(1), c = 11.129(1)Å; α = 105.24(2), ß = 91.87(3), γ = 90.92(1)°, R₁ = 0.034.     

Direct Electron Transfer and Bioelectrocatalysis by a Hexameric,Heme Protein at Nanostructured Electrodes

A nanohybrid consisting of poly(3‐aminobenzenesulfonic acid‐co‐aniline) and multiwalled carbon nanotubes [MWCNT‐P(ABS‐A)]) on a gold electrode was used to immobilize the hexameric tyrosine‐coordinated heme protein (HTHP). The enzyme showed direct electron transfer between the heme group of the protein and the nanostructured surface. Desorption of the noncovalently bound heme from the protein could be excluded by control measurements with adsorbed hemin on aminohexanthiol‐modified electrodes. The nanostructuring and the optimised charge characteristics resulted in a higher protein coverage as compared with MUA/MU modified electrodes. The adsorbed enzyme shows catalytic activity for the cathodic H₂O₂ reduction and oxidation of NADH.     

Surface‐Tuned Electron Transfer and Electrocatalysis of Hexameric Tyrosine‐Coordinated Heme Protein

Molecular modeling, electrochemical methods, and quartz crystal microbalance were used to characterize immobilized hexameric tyrosine‐coordinated heme protein (HTHP) on bare carbon or on gold electrodes modified with positively and negatively charged self‐assembled monolayers (SAMs), respectively. HTHP binds to the positively charged surface but no direct electron transfer (DET) is found due to the long distance of the active sites from the electrode surfaces. At carboxyl‐terminated surfaces, the neutrally charged bottom of HTHP can bind to the SAM. For this “disc” orientation all six hemes are close to the electrode and their direct electron transfer should be efficient. HTHP on all negatively charged SAMs showed a quasi‐reversible redox behavior with rate constant k_s values between 0.93 and 2.86 s^?1 and apparent formal potentials ${E{{0{^{\prime }}\hfill \atop {\rm app}\hfill}}}$ between ‐131.1 and ‐249.1 mV. On the MUA/MU‐modified electrode, the maximum surface concentration corresponds to a complete monolayer of the hexameric HTHP in the disc orientation. HTHP electrostatically immobilized on negatively charged SAMs shows electrocatalysis of peroxide reduction and enzymatic oxidation of NADH.     

Template‐Dependent Photochemical Reactivity of Molecular Metal Oxides

A combined experimental and theoretical study shows that the photooxidative activity of two isostructural metal oxide clusters depends on their internal templates. To this end, two halide‐templated bismuth vanadium oxide clusters [X(Bi(dmso)₃)₂V₁₂O₃₃]^? (X=Cl^?, Br^?) are reported and fully characterized. The two clusters show similar absorption features and illustrate that bismuth incorporation results in increased visible‐light absorption. Significantly higher photooxidative activity is observed for the bromide‐templated cluster compared with the chloride‐templated one. Detailed photophysical assays and complementary DFT calculations suggest that the more efficient triplet excited state formation in the Br^?‐containing cluster is the decisive step in the photocatalysis and is due to the heavy‐atom effect of the bromide. This concept can therefore open new pathways towards the optimization of photocatalytic activity in metal oxide clusters.     

Reactivity of the Donor‐Stabilized Silylenes [iPrNC(Ph)NiPr]2Si and [iPrNC(NiPr2)NiPr]2Si: Activation of CO2 and CS2

Activation of CO₂ by the bis(amidinato)silylene 1 and the analogous bis(guanidinato)silylene 2 leads to the structurally analogous six‐coordinate silicon(IV ) complexes 4 (previous work) and 8 , respectively, the first silicon compounds with a chelating carbonato ligand. Likewise, CS₂ activation by silylene 1 affords the analogous six‐coordinate silicon(IV ) complex 10 , the first silicon compound with a chelating trithiocarbonato ligand. CS₂ activation by silylene 2 , however, yields the five‐coordinate silicon(IV ) complex 13 with a carbon‐bound CS₂^2? ligand, which also represents an unprecedented coordination mode in silicon coordination chemistry. Treatment of the dinuclear silicon(IV ) complexes 5 and 6 with CO₂ also affords the six‐coordinate carbonatosilicon(IV ) complexes 4 and 8 , respectively.     

Selective Formation of a Trisubstituted Alkene Motif by trans‐Hydrostannation/Stille Coupling: Application to the Total Synthesis and Late‐Stage Modification of 5,6‐Dihydrocineromycin B

Countless natural products of polyketide origin have an E‐configured 2‐methyl‐but‐2‐en‐1‐ol substructure. An unconventional entry into this important motif was developed as part of a concise total synthesis of 5,6‐dihydrocineromycin B. The choice of this particular target was inspired by a recent study, which suggested that the cineromycin family of antibiotics might have overlooked lead qualities, although our biodata do not necessarily support this view. The new approach consists of a sequence of alkyne metathesis followed by a hydroxy‐directed trans‐hydrostannation and a largely unprecedented methyl‐Stille coupling. The excellent yield and remarkable selectivity with which the signature trisubstituted alkene site of the target was procured is noteworthy considering the rather poor outcome of a classical ring‐closing metathesis reaction. Moreover, the unorthodox ruthenium‐catalyzed trans‐hydrostannation is shown to be a versatile handle for diversity‐oriented synthesis.