Synthesis and characterisation of a new vanadyl oxalatophosphate compound: (C10H10N2)[(VO)(HPO4)]2(C2O4)

A new vanadyl oxalatophosphate compound, (C₁₀H₁₀N₂)[(VO)(HPO₄)]₂(C₂O₄), was synthesized via the hydrothermal approach and characterised structurally using single-crystal X-ray diffraction, FT-IR and thermogravimetric analysis. The compound has two-dimensional anionic layers with occupying the interlayer spaces.     

Syntheses and structures of two copper-molybdate complexes: The 3-D [Cu(4,4′-bpy)(MoO4)] and 1-D [Cu2(HDABCO)2(H2Mo8O27)] · 4H2O

Hydrothermal reaction of molybdenum oxide and copper(II) source in the presence of 4,4′-bipyridine (4,4′-bpy) afforded three-dimensional covalent framework [Cu^II(4,4′-bpy)(MoO₄)] (1), while reaction with 1,4-diazoniabicyclo[2,2,2]octane (DABCO) in place of 4,4′-bpy and addition of metal molybdenum resulted in one-dimensional chain-like compound . The copper in 1 is divalent and approximately shows trigonal bipyramidal geometry, while in 2 is monovalent and approximately shows T-shaped geometry. The structure of 1 has a three-dimensional pillar-layered framework constructed from bimetallic {CuMoO₄} layers bridged by bifunctional ligand 4,4′-bpy. Interestingly, the {CuMoO₄} layer in 1 consists of 16-membered {Cu₄Mo₄O₈} rings and 8-membered {Cu₂Mo₂O₄} rings, different from other reported {CuMoO₄} layers. The structure of 2 consists a one-dimensional chain that is attached by peripheral {Cu(HDABCO)}²⁺ units. The chain is constructed from octamolybdates through common corners.     

Excited state properties of Tl2B12H12. Metal-centered photoluminescence

The compound Tl₂B₁₂H₁₂ which consists of icosahedral anions and Tl⁺ cations shows a metal-centered r.t. luminescence at λ_max = 530 nm which originates from the lowest-energy sp triplet of Tl⁺. This emission indicates a considerable covalent interaction between Tl⁺ and which is based on the hydridic nature of the boron cluster.     

On the mechanism of formation and spectral properties of radical anions generated by the reduction of -[Re(CO)3(5-nitro-1,10-phenanthroline)] and -[Re(CO)3(3,4,7,8-tetramethyl-1,10-phenanthroline)] pendants in poly-4-vinylpyridine polymers

The electrochemical reduction in aprotic media of -[Re^I(CO)₃L]⁺ pendants in poly-4-vinylpyridine polymers is compared to that of [Re^I(CO)₃L]⁺ complexes (L = 5-nitro-1,10-phenanthroline and 3,4,7,8-tetramethyl-1,10-phenanthroline). The UV-Vis absorption spectra of the reduced radical anions of 5-nitro-1,10-phenanthroline (NO₂-phen) and 3,4,7,8-tetramethyl-1,10-phenanthroline (tmphen) were obtained by spectro-electrochemistry of [Re^I(CO)₃(NO₂-phen)(CH₃CN)]⁺ and [Re^I(CO)₃(tmphen)(CH₃CN)]⁺, respectively. Similar spectra were obtained for the radical anions -phen and tmphen⁻ after pulse radiolysis experiments with -[Re^I(CO)₃L]⁺-containing polymers. The analysis of the time-resolved difference spectra was performed using “multivariate curve resolution” (MCR) techniques. Unlike , CH₂OH radicals were unable to reduce tmphen ligands. The reaction of and/or CH₂OH with -[Re^I(CO)₃(NO₂-phen)]⁺-containing polymers generates -[Re^I(CO)₃(-phen)] pendants which after disproportionation give rise to products with λ_max = 380 nm. The kinetic behavior of -[Re^I(CO)₃(-phen)] pendants under different experimental conditions is discussed.     

Formation of an observable intermediate during the reduction of [Co(NH3)5CN] by CRR(OH) radicals

CR¹R²OH, Rⁱ = CH₃ or H, react with the complex [Co^III(NH₃)₅CN]²⁺ to form an observable intermediate probably via bonding to the nitrogen of the cyanide. This intermediate isomerizes to form a second intermediate. The second intermediate decomposes into Co²⁺(aq), 5NH₄⁺, CN⁻ and R¹R²CO. The plausible structures of the intermediates are discussed. The radicals CH³, CH₂CHO, , and are considerably less reactive towards this complex, the formation of intermediates in their presence is not observed.     

Coordination and derivatization of 3, 4, and 6-membered nitrogen heterocycles at a chiral tungsten(II) center

Reaction of [Tp′W(CO)₂(PhCCPh)][OTf] (1b) (Tp′ = hydridotris(3,5-dimethylpyrazolyl)borate) with excess aziridine or 2-methylaziridine followed by protonation with produces chiral tungsten(II) amine complexes (3, 4; R = Me, Ph). An azetidine amido complex, Tp′W(CO)(PhCCMe)(H₂) (5) is synthesized by reaction of [Tp′W(CO)₂(PhCCMe)][OTf] (1a) with excess azetidine. Oxidation of amido complex 5 with I₂ in the presence of a weak base provides the corresponding 1-azetine complex, (6). Addition of methylmagnesium bromide to complex 6 results in formation of predominantly one diastereomer (S_WR_C/R_WS_C) (96:4 dr) of the 2-methylazetidine complex, Tp′W(CO)(PhCCMe)(H₂) (7). Reaction of complex 5 with results in formation of a cationic azetidine complex, (8). Reaction of 1b with excess piperidine followed by oxidation affords 2,3,4,5-tetrahydropyridine complex 9b, . Formation of an enamido complex, Tp′W(CO)(PhCCPh)(H₂) (10), is observed upon addition of base to 9b. Subsequent addition of [D⁺] to the enamido β-carbon results in the formation of the deuterated product, 9b-d₁, as determined by ²H NMR. Seven X-ray crystal structures have been determined, and these encompass complexes with 3, 4, and 6-membered heterocyclic ligands. Crystal structures are reported for two aziridine adducts (2, 4) two neutral amido complexes (5, 7), one cationic imine complex (6), and one cationic amine (8) complex derived from azetidine, and the imine complex formed from piperidine (9).     

Kinetics and mechanism of the oxidation of oxalic acid by tetrachloroaurate(III) ion

The oxidation of oxalic acid by tetrachloroaurate(III) ion in 0.005 ? [HClO₄] ? 0.5 mol dm⁻³ is first order in and a fractional order in [oxalic acid], the reactive entities being AuCl₃(OH)⁻ and ions. The pseudo first-order rate, k_obs, with respect to [Au(III)], is retarded by increasing [H⁺] and [Cl⁻]. The retardation by H⁺ ion is caused by the dissociation equilibrium . A mechanism in which a substitution complex, is formed from AuCl₃(OH)⁻ and ions prior to its rate limiting disproportionation into products is suggested. The rate limiting constant, k, has been evaluated and its activation parameters are reported. The equilibrium constant K₁ for the formation of the substitution complex and its thermodynamic parameters are also reported.     

A Thermodynamic Funnel Drives Bacterial Lipopolysaccharide Transfer in the TLR4 Pathway

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