Synthesis and Luminescence Properties of Three High-dimensional Coordination Polymers:Zn(Ⅱ) with Imidazole or Benzimidazole Ligand

A novel 2D coordination polymer [Zn2(bim)4]n(1)(Hbim=benzimidazole) based on dihydrated-[N,N'-bis(2-aminophenl)-oxalamide](L1·2H2O) with zinc nitrate has been synthesized.Previously we have synthe-sized complexes [In2Zn3(im)12]n(2)(Him= imidazole) and [Zn(im)2]n(3) successfully.In complex 1,each Zn(Ⅱ) coor-dinated with four ligands adopts a distorted tetrahedron coordination mode,and the 2D grid structure is built by the Zn(bim)4 as the secondary building unit(SBU).The luminescence properties of the three c...     

Diversity of coordination architecture of silver(Ι) complexes with different 2-aminopyrimidyl derivatives: Effect of counter anions and ligands

Five new silver(Ι) complexes of the formula [Ag(L₁)(CF₃SO₃)(H₂O)]_n (1), [Ag₄(L₁)₄(CF₃CO₂)₄]_n (2), [Ag₂(L₁)₄(ClO₄)₂] (3), [Ag(L₂)(ClO₄)]_n (4), and [Ag(L₃)(ClO₄)]_n (5) have been synthesized by reactions of varied silver(Ι) salts with the corresponding 2-aminopyrimidyl ligands (namely, 2-amino-4,6-dimethylpyrimidine (L₁), 2-amino-4-methoxy-6-methylprimidine (L₂), and 2-amino-4,6-dimethoxyprimidine (L₃)). The influences of counter anions and ligands on the structure of the complexes are discussed. Two complexes, 1 with one-dimensional (1D) zigzag chain and 2 with 1D ladder network are obtained by using the same ligand L₁ but different silver(Ι) salts. On the other hand, using the same silver(Ι) perchlorate but different ligands under the same synthetic conditions, complexes 3–5 are isolated, respectively. In the case of 3, two metal atoms and four L₁ ligands form dimeric [Ag₂(L₁)₄] unit further connected by intermolecular hydrogen bonds and π–π interactions to form an infinite 2D layer structure. Complex 4 displays a two-dimensional (2D) grid network. Complex 5 has a 1D zigzag chain but different from that of 1. An extended 3D framework arises from N–H···O intermolecular hydrogen bonds and Ag···O weak interaction. The results reveal that the nature of the counter anions and organic ligands all has great impact on the structure of the complexes. In addition, the hydrogen-bonding interactions and π–π stacking also play important roles in the formation of supramolecular architectures, for instance, to link low-dimensional entities to high-dimensional frameworks. The luminescence properties of the synthesized silver complexes were investigated in the solid state at room temperature.     

Coordination chemistry of H-spirophosphorane ligands towards pentacarbonylchlororhenium(I) – synthesis,structure and catalytic activity of complexes

Synthesis of a group of carbonyl rhenium coordination compounds with hydrospirophosphorane ligands was carried out and described. Different symmetrical HP(OCH₂CH₂NH)₂ L1 , HP(OCH₂CMe₂NH)₂ L2 , HP(OC₆H₄NH)₂ L3 , and unsymmetrical ligands HP (OCMe₂CMe₂O)(OC₆H₄NH) L4 were found to coordinate to the rhenium center as bidentate P,N donor ligands yielding fac-[ReCl (CO)₃ Ln ], where n = 1 – 4. Furthermore, monodentate coordination was also observed in some cases, as was clearly presented in the case of [ReCl(CO)₂( L4- κ²P,N)( L4- κP)] complex. All of the complexes were characterized using optical spectroscopy. Single-crystalX-ray diffraction was also performed in the case of fac-[ReCl(CO)₃ L3 ], fac-[ReCl(CO)₃ L4 ], [Re(CO)₂( L2 )₂]Cl and [ReCl (CO)₂( L4- κ²P,N)( L4- κP)] samples. Complexes [ReCl(CO)₃ L3 ] and [ReCl (CO)₃ L4 ], both bearing rings of conjugated double bonds within hydrospirophosphorane ligands, exhibited luminescence. Catalytic properties of rhenium complexes were assessed using the representative fac-[ReCl (CO)₃ L2 ] complex in the dimerization reaction of terminal alkynes. An efficient and selective procedure for synthesis of the E - enynes was developed. Coupling of (2-chlorophenyl)acetylene was mediated by [ReCl (CO)₃ L2 ]/TBAF system with a 100% conversion rate. Different substituents within aromatic alkynes were tolerated and the resulting products were dependent on the nature of the substituents.     

Is there a homolytic substitution chemistry (SH2) of sulfones?

[reaction: see text] A series of 2-alkylsulfonyl-2'-biphenyl radicals, in which the alkyl group is primary, secondary, or tertiary, were generated and the products of their reactions investigated. Dibenzothiophene S,S-dioxide was not identified among the products, which arose mainly from intramolecular hydrogen abstraction from the alkyl group or addition to the solvent, benzene. On this basis, it is concluded that homolytic substitution at sulfonyl sulfur, if possible at all, is too slow to take precedence over a number of competing decomposition pathways. Previous literature results suggesting the possibility of intramolecular homolytic substitution at sulfonyl sulfur may be explained by alternative processes.     

Coordination of N2 ligands to lanthanum: the complexes La (N2)1–8

Structural Chemistry - The structures and bonding properties of La(N2)x (x?=?1–8) complexes were investigated by density functional theory (DFT) computations using the B3LYP...     

A sugar's choice: coordination to a mononuclear or a dinuclear copper(II) complex?

We proposed a decisive role of the number of metal ions at the sugar binding site for carbohydrate-coordinating copper(II) complexes. To verify this hypothesis, we studied the binding of the representatively chosen carbohydrates D-ribose (7), D-mannose (8), D-glucose (9), and D-maltose (10) to structurally related mono- and dinuclear copper(II) complexes in alkaline solution. All carbohydrates coordinate to the metal complexes in a 1:1 molar ratio. Coordination of 7 or 8 to the dinuclear copper(II) complex 1 is about 0.5 order of magnitude stronger than the complex formation with related mononuclear complexes. On contrast, 9, which is an epimer of 8, coordinates stronger to either one of the mononuclear copper(II) complexes in alkaline aqueous solution.     

Coordination chemistry and biological activity of nickel(II) and copper(II) ion complexes with nitrogen–sulphur donor ligands derived from S-benzyldithiocarbazate (SBDTC)

A bidentate and a quadridentate Schiff base having NS and NNSS donor sequences were prepared by condensing S-benzyldithiocarbazate (NH₂NHCSSCH₂Ph) with 2,3-butanedione (1:1 and 1:2 mole ratio). Ni^II and Cu^II complexes of these ligands were studied and characterised by elemental analyses and various physico-chemical techniques. The nickel complexes, [Ni(NS)₂] and [Ni(SNNS)], were diamagnetic with square-planar and five-coordinate structures, respectively. The copper complex was, however, pentacoordinated. The ligands and the complexes were screened for anticancer activity against T-lymphoblastic leukemic cells (CEM-SS) and colon cancer cells (HT-29). The NS Schiff base was strongly active against leukemic cells with a CD₅₀ value of 2.05 g cm^–3. The nickel and copper complexes were found to be stronger antioxidants than Vitamin E.     

Coordination chemistry of alkali and alkaline earth cations—synthesis and X-ray structural analysis of sodium(picrate)-(1,10-phenanthroline)2

The complex Na(Pic)(PHEN)₂ (Pic = picrate, Phen = 1,10-phenanthroline) is unique in being a cluster with two independent Na ions in the asymmetric unit. Na(1) is seven-coordinated involving two N atoms of two Phen molecules (NaN, 2.492–2.622 Å), phenoxide O (NaO⁻, 2.381 Å) and an o-nitro-oxygen (NaONO, 2.584 Å) of Pic(1) and also to the phenoxide O (NaO⁻, 2.656 Å) of Pic(2). Na(2) is six-coordinated through four N atoms of the two other Phen molecules (NaN, 2.510–2.570 Å), phenoxide O (NaO⁻, 2.317 Å) and o-nitro-oxygen (NaONO, 2.592 Å) of Pic(2). Thus Pic(2) serves as a linkage residue between two clusters. The Phen molecules are planar and nearly perpendicular to each other in either cluster.     

Crystal Structure and Luminescence with Relative Principles Calculation of a New One-dimensional Zn(Ⅱ) Coordination Polymer

A new coordination polymer, namely [ZnBr(bmb)(Hbmb)]_n(1)(Hbmb = 3-benzoimidazol-1-yl-benzoic acid), has been synthesized through a hydrothermal method and characterized by single-crystal X-ray diffraction, elemental analysis, infrared spectra, thermogravimetric analysis, and fluorescent characterization. The crystal structure is of triclinic system, space group P1 with a = 10.637(3), b = 11.660(3), c = 12.406(3) ?, α = 103.462(3), β = 105.144(3), γ = 110.513(3)o, V = 1298.5 ?~3, C_(28)H_(19)N_4O_4 ZnBr, Mr = 624.0, Z = 2, Dc = 1.588 g/cm~3, F(000) = 624, the final R = 0.0253 and w R = 0.0616 for 4385 observed reflections. The polymer features a chain-like structure and stabilizes itself by interchain hydrogen bonds to form a 2D supramolecular structure. 1 exhibits a strong blue emission with a fluorescent lifetime of 1.13 ns, and emitting mechanism of ligand-centered charge transition also was confirmed by the first-principle calculation.     

4′-(2-Methylphenyl)-2,2′:6′,2″-terpyridine: coordination chemistry with Ni(II), Cu(II), Zn(II) and Ag(I)

The synthesis of 4′-(2-methylphenyl)-2,2′:6′,2″-terpyridine (L) has been improved. The coordination chemistry of the ligand was explored using Ni(II), Cu(II), Zn(II), and Ag(I) ions. X-ray crystallography, elemental analysis, NMR, and mass spectrometry were used to characterize the 13 new compounds that have been synthesized. Under different reaction conditions, Ni(II), Cu(II), and Zn(II) produced discrete complexes, sometimes containing more than one metal ion, while Ag(I) furnished a polymeric spiral complex in which the central pyridine nitrogen of each terpyridine ligand bridges two Ag(I) ions. Crystallographically characterized complexes are [Ni(L)₂]Cl₂, [Ni₂Cl₄(L)₂], [Ni(L)(OH₂)₃]Cl₂, [Ni(L)₂]Br₂, [Cu(L)(OH₂)(OSO₃)], [Cu₃Cl₆(L)₂], [Cu(L)(OH)(OH₂)₂]PF₆, [Cu(L)₂](OTf)₂, [Cu(L)(OAc)₂], [Zn(L)(OAc)₂], [Zn(L)Cl₂], [Zn(L)₂](NO₃)₂, [{Ag₂(μ-L)₂(μ-NO₃)}_n](NO₃)_n.     

A New Three-dimensional Zn(Ⅱ) Coordination Polymer Based on Trinuclear Zn(Ⅱ) Units with a Three-fold Hex Topology

Under solvothermal conditions, a new trinuclear Zn(II) complex, [Zn3(bpdc)3(DPNDI)]· 3NMF(1, H2 bpdc = biphenyl-4,4-dicarboxylate, N,N-di(4-pyridyl)-1,4,5,8-naphthalenetetracarboxydiimide(DPNDI) and NMF = N-methylformamide), has been synthesized with mixed organic ligands. Complex 1 is of monoclinic, space group P21/n with a = 11.167(5), b = 14.806(5), c = 19.494(5) , V = 3154.6(19) 3, Z = 2, Mr = 1455.24, Dc =1.532 g/cm3, F(000) =1484 and μ = 1.212 mm1. The final refinement gave R = 0.0343 and w R = 0.0419 for 6209 reflections with I 2(I). Single-crystal X-ray analysis reveals that complex 1 features a 3D structure based on the trinuclear Zn(II) units. Complex 1 shows three-fold interpenetrating hex topology. Furthermore, the luminescent property 1 is investigated.     

Efficacious selective separation of U(Ⅵ) over Mo(Ⅵ) using novel 2,9-diamide-1,10-phenanthroline ligands: Liquid-liquid extraction and coordination chemistry

Uranium and molybdenum are important strategic elements. The production of ⁹⁹Mo and the hydrometallurgical process of uranium ore face difficult problems of separation of uranium and molybdenum.In this study, the four phenanthroline diamide ligands were synthesized, and extraction and stripping experiments were performed under different conditions to evaluate the potential application of these ligands for separation of U(Ⅵ) over Mo(Ⅵ). With the growth of alkyl chain, the solubility of...     

Synthesis and reactivity of (μ-η2:η2-peroxo)dicopper(II) complexes with dinucleating ligands: Hydroxylation of xylyl linker with a NIH shift

New hexadentate dinucleating ligands having a xylyl linker, X–L–R, were synthesized, where X–L–R = 1,3-bis[bis(6-methyl-2-pyridylmethyl)aminomethyl]-2,4,6-trimethybenzene (Me₂–L–Me) and 1,3-bis[bis(6-methyl-2-pyridylmethyl)aminomethyl]-2-fluorobenzene (H–L–F). They form dinuclear copper(I) complexes, [Cu₂(X–L–R)]²⁺ (Me₂–L–Me (1) and H–L–F (2)). The copper(I) complexes in acetone at −78 °C react with O₂ to produce intra- and intermolecular (μ-η²:η²-peroxo)dicopper(II) species depending on the concentrations of the complexes:  both complexes generate intramolecular (μ-η²:η²-peroxo)dicopper(II) species [Cu₂(O₂)(X–L–R)]²⁺ (1-O₂ and 2-O₂) at the concentrations below ∼5 mM, whereas at ∼60 mM, both complexes produce intermolecular (μ-η²:η²-peroxo)dicopper(II) species, which were confirmed by the electronic and resonance Raman spectroscopies.  The electronic spectrum of 1-O₂ in acetone at concentrations below ∼5 mM showed an absorption band at (λ_max = 442 nm, ε = 5600 M⁻¹ cm⁻¹) assignable to the ${\mathrm{\pi }}_{\sigma }^1$(O–O)-to-Cu(II) ($({\text{d}}_{x^2-y^2}+{\text{d}}_{x^2-y^2})$ component) LMCT transition in addition to an intense band attributable to the ${\mathrm{\pi }}_{\sigma }^1$(O–O)-to-Cu(II) ($({\text{d}}_{x^2-y^2}-{\text{d}}_{x^2-y^2})$ component) LMCT transition (λ_max = 359 nm, ε = 21000 M⁻¹ cm⁻¹), indicating that the (μ-η²:η²-peroxo)Cu(II)₂ core of 1-O₂ takes a butterfly structure. Decomposition of 1-O₂ resulted in hydroxylation of the 2-position of the xylyl linker with 1,2-methyl migration (NIH shift), suggesting that the hydroxylation reaction proceeds via a cationic intermediate as proposed for closely related (μ-η²:η²-peroxo)Cu(II)₂ complexes having a xylyl linker. Kinetic study of the decomposition (hydroxylation of the xylyl linker) of 1-O₂ suggests that a stereochemical effect of the methyl group in the 2-position of the xylyl linker has a significant influence on a transition state for decomposition (hydroxylation of the xylyl linker).     

Coordination polymer with a staircase molecular architecture: Connecting binuclear Zn(II) bis-chelate platforms with bridging 4,4′-bipyridyl

A new tetraketone ligand with two separated β-diketone functions was prepared, 1,3-[CO-CH₂-COC(CH₃)₂OCH₃]₂Ph (H₂L ^iPrOMe). The title coordination polymer, [Zn₂(L ^iPrOMe)₂(DMSO)₂(bipy)]_n (DMSO = dimethylsulfoxide; bipy = 4,4′-bipyridyl), formed as the only crystalline product upon interaction of Zn(II) acetate, H₂L ^iPrOMe and bipy in 1:1:1 to 1:1:5 molar ratios in DMSO as a solvent. A single crystal XRD study of the compound revealed a staircase polymeric architecture of the complex. The architecture is based on binuclear ′Zn₂(L ^iPrOMe)_2′ platforms where each Zn(II) cation is chelated by two β-diketonate groups of two L ^iPrOMe ligands in the equatorial plane, while each L ^iPrOMe ligand chelates two Zn(II) cations. The coordination environment of each Zn(II) is completed to a distorted octahedron by an O atom of a terminal DMSO and an N atom of bridging bipy ligands. The resulting staircase polymeric ribbons are packed in a self-inclusion mode as would be expected for van der Waals interactions. Most fragments of the molecule were found to be disordered over two equally populated orientations, which was interpreted as evidence of a modulated structure. In addition, several fragments reveal additional minor disordering and high thermal motion.     

Catalytic Ni(II) in reactions of SmI2: Sm(II)- or Ni(0)-based chemistry?

The addition of catalytic amounts of Ni(II) salts provide enhanced reactivity and selectivity in numerous reactions of SmI(2), but the mechanistic basis for their effect is unknown. We report spectroscopic and kinetic studies on the mechanistic role of catalytic Ni(II) in the samarium Barbier reaction. The mechanistic studies presented herein show that the samarium Barbier reaction containing catalytic amounts of Ni(II) salts is driven solely by the reduction of Ni(II) to Ni(0) in a rate-limiting step. Once formed, Ni(0) inserts into the alkyl halide bond through oxidative addition to produce an organonickel species. During the reaction, the formation of colloidal Ni(0) occurs concomitantly with Ni(0) oxidative addition as an unproductive process. Overall, this study shows that a reaction thought to be driven by the unique features of SmI(2) is in fact a result of known Ni(0) chemistry.     

μ-Coordination chemistry of NO ligands: Adducts of trans-Mo(dmpe)2(H)(NO) with lithium salts

Four adducts were formed by the reaction of trans-Mo(dmpe)₂(H)(NO) (1) (dmpe = bis(dimethylphosphino)ethane) and a respective lithium reagent to afford, [Mo(dmpe)₂(H)(NO)LiHBEt₃]₂ (2), [Mo(dmpe)₂(H)(NO)LiN(SiMe₃)₂]₂ (3), [Mo(dmpe)₂(H)(NO)]₃(LiBH₄)₂ (4), and {[Mo(dmpe)₂(H)(NO)]₂[LiBH₄]₅}_n (5). Structures 2-5 were characterized by crystal X-ray diffraction analyses. Structures 2 and 3 revealed to be dimers of the 1:1 adduct of 1 and the lithium salt. The two nitrosyl oxygen atoms in 2 are μ₂-bridged connecting two separate LiHB(C₂H₅)₃ moieties, whereas in 3 these oxygen atoms exhibit a terminal coordination mode binding to two lithium ions of the dimeric [LiN(SiMe₃)₂]₂ unit. Structure 4 shows a discrete structure formed by two separate mononuclear LiBH₄ units being bridged by the nitrosyl oxygen atoms of three Mo(dmpe)₂(H)(NO) moieties. Structure 5 displays a complicated chain structure with differently coordinated lithium centers, various types of bridging BH₄ and bridging nitrosyl groups.     

Addition and redox reactivity of hydrogen sulfides (H2S/HS⁻) with nitroprusside: new chemistry of nitrososulfide ligands

The nitroprusside ion [Fe(CN)(5)NO](2-) (NP) reacts with excess HS(-) in the pH range 8.5-12.5, in anaerobic medium ("Gmelin" reaction). The progress of the addition process of HS(-) into the bound NO(+) ligand was monitored by stopped-flow UV/Vis/EPR and FTIR spectroscopy, mass spectrometry, and chemical analysis. Theoretical calculations were employed for the characterization of the initial adducts and reaction intermediates. The shapes of the absorbance-time curves at 535-575 nm depend on the pH and concentration ratio of the reactants, R=[HS(-)]/[NP]. The initial adduct [Fe(CN)(5)N(O)SH](3-) (AH, λ(max) ≈570 nm) forms in the course of a reversible process, with k(ad)=190±20 M(-1)s(-1) , k(-ad)=0.3±0.05 s(-1) . Deprotonation of AH (pK(a)=10.5±0.1, at 25.0 °C, I=1 M), leads to [Fe(CN)(5)N(O)S](4-) (A, λ(max)=535 nm, ε=6000±300 M(-1) cm(-1) ). [Fe(CN)(5)NO](.)(3-) and HS(2)(.)(2-) radicals form through the spontaneous decomposition of AH and A. The minor formation of the [Fe(CN)(5)NO](3-) ion equilibrates with [Fe(CN)(4)NO](2-) through cyanide labilization, and generates the "g=2.03" iron-dinitrosyl, [Fe(NO)(2)(SH)(2)](-) , which is labile toward NO release. Alternative nucleophilic attack of HS(-) on AH and A generates the reactive intermediates [Fe(CN)(5)N(OH)(SH)(2)](3-) and [Fe(CN)(5)N(OH)(S)(SH)](4-) , respectively, which decompose through multielectronic nitrosyl reductions, leading to NH(3) and hydrogen disulfide, HS(2)(-) . N(2)O is also produced at pH≥11. Biological relevance relates to the role of NO, NO(-) , and other bound intermediates, eventually able to be released to the medium and rapidly trapped by substrates. Structure and reactivity comparisons of the new nitrososulfide ligands with free and bound nitrosothiolates are provided.     

Triethanolamine zinc phosphite, (C6H13NO3)Zn2(HPO3): a templated network or a network of clusters?

(C6H13NO3)Zn2(HPO3) (I) displays an extended hybrid organic/inorganic structure in which the triethanolamine organic species acts as an anionic tetradentate ligand, rather than a typical protonated cationic template. Crystal data for I: Mr = 357.89, monoclinic, P2(1)/c (no. 14), a = 8.4216(4) angstroms, b = 9.9262(5) angstroms, c = 12.8494(6) angstroms, beta = 91.824(1) degrees, V = 1073.6(1) angstroms3, Z = 4.     

Coordination chemistry of a new imine-ether ligand,N,N′-bis(2-pyridylmethylene)-2,2′-(ethylenedioxy)bis(ethylamine): mono-helical and single-helical-strand coordination modes identified by X-ray crystallography

A new Schiff base ligand, N,N′-bis(2-pyridylmethylene)-2,2′-(ethylenedioxy)bis(ethylamine), L, and the complexes, [AgL](BF₄) (1), [Zn₂LCl₄] (2), [Hg₂LCl₄] (3), [Cd₂LI₄] (4), [Ni₂L₃](BF₄)₄ (5), and [M₂L₃](ClO₄)₄ with M=Co(II) (6) Fe(II) (7) and Zn(II) (8), have been synthesised and characterised crystallographically and spectroscopically. The silver(I) complex 1 consists of a mono-helical structure where one ligand molecule, coordinating in a tetradentate manner, wraps itself around the Ag(I) ion, giving rise to a distorted tetrahedral arrangement. Single-helical-strand binuclear complexes were obtained with zinc(II), mercury(II) and cadmium(II), 2, 3 and 4, respectively. Complexes 2 and 3 are isomorphous and both contain one ligand molecule coordinating to two metal atoms via the two pyridylimine N-atoms. The two remaining coordination sites on the metals are occupied by chlorine atoms. In the fivefold coordinate cadmium(II) complex, 4, the ligand coordinates in a bis-tridentate manner via the two pyridylimine units and the two oxygen atoms. The two remaining coordination sites on the metals are occupied by iodine atoms. It was possible to combine both coordination modes of the ligand, mono-helical and single-helical-strand, in the isomorphous binuclear octahedrally coordinated nickel(II), cobalt(II), iron(II) and zinc(II) complexes, 5–8, respectively. One ligand molecule is wrapped around each metal ion, which in turn are linked by a third ligand molecule, so forming mono-bridged species.     

Coordination chemistry of silones: Synthesis and reactivity of new silicon-disubstituted (η4-silole) complexes

The synthesis of some new silicon-disubstituted (η⁴-2,5-diphenylsilacyclopentadiene)tricarbonyliron complexes are described. Stable complexes with various functional groups attached at silicon have been isolated. The exo position shows an enhanced reactivity, and cleavage of an SiH bond at this position occurs selectively with retention.