Fang Rui-Qin, Zhang Xian-Ming
School of Chemistry & Material Science, Shanxi Normal University, Linfen 041004, P. R. China.
Inorg Chem. 2006 Jun 12;45(12):4801-10. doi: 10.1021/ic052099m.
Seven complexes of metal 4,5-dicarboxyimidazole acid (H3dcbi), namely, [Cd(H2dcbi)2(H2O)3].H2O (1.alpha), [Cd(H2dcbi)2(H2O)2].2H2O (1.beta), [Cd(H2dcbi)2(H2O)2].2H2O (1.gamma), [Cd(H2dcbi)2(H2O)2] (2), [Cd(Hdcbi)(H2O)] (3), [Cd5(Hdcbi)2(dcbi)2(H2O)].XH2O (4), [Cd2(Hdcbi)(C2O4)] (5), [Ag5(Hdcbi)2(CN)] (6), and [Mn(Hdcbi)(H2O)] (7), have been hydro(solvo)thermally synthesized by fine control over synthetic conditions such as stoichiometry, solvent, and pH value. X-ray single-crystal structural analyses reveal that they have rich structural chemistry ranging from mononuclear (1), one-dimensional (2), and two-dimensional (3 and 7) to three-dimensional (4-6), among which 1 crystallizes in three types (alpha, beta, and gamma) of polymorphs. Seven coordination modes of H(n)dcbi ranging from monodentate to mu5 have been observed, among which four modes are found first. The coordination geometries of the Cd(II) sites vary from five-coordinate trigonal bipyramid and square pyramid, six-coordinate octahedron to seven-coordinate pentagonal bipyramid. Analyses of the synthetic conditions and structures of the Cd(II) complexes show that the influences of the solvent and the metal-to-ligand molar ratio are very important to the products and coordination modes of H(n)dcbi (n =0, 1, 2). Studies of the coordination modes of H(n)dcbi and the structures of the Cd(II) complexes also reveal that the singly deprotonated H2dcbi generally coordinates in the monodentate imidazole-N or N,O-chelate mode to result in mononuclear structures, the doubly deprotonated Hdcbi coordinates in the mu2, mu3, or mu4 mode to generate one-dimensional or two-dimensional structures, and the triply deprotonated dcbi can coordinate in the mu5 mode to form three-dimensional structures. The cyanide was in situ formed via C-C bond cleavage of acetonitrile during the preparation of 6, which adopts a rare mu4-kC,kC:kN,kN mode to bridge four Ag(I) ions. The microporous three-dimensional framework of 4 is maintained after the removal of the guest molecules. Compounds 1-5 show strong violet emissions with maxima around 380 nm, tentatively attributed to the ligand-centered transition.
通过精确控制化学计量比、溶剂和pH值等合成条件,水(溶剂)热合成了七种金属4,5 - 二羧基咪唑酸(H₃dcbi)配合物,即[Cd(H₂dcbi)₂(H₂O)₃]·H₂O(1.α)、[Cd(H₂dcbi)₂(H₂O)₂]·2H₂O(1.β)、[Cd(H₂dcbi)₂(H₂O)₂]·2H₂O(1.γ)、[Cd(H₂dcbi)₂(H₂O)₂](2)、[Cd(Hdcbi)(H₂O)](3)、[Cd₅(Hdcbi)₂(dcbi)₂(H₂O)]·XH₂O(4)、[Cd₂(Hdcbi)(C₂O₄)](5)、[Ag₅(Hdcbi)₂(CN)](6)和[Mn(Hdcbi)(H₂O)](7)。X射线单晶结构分析表明,它们具有丰富的结构化学,范围从单核(1)、一维(2)、二维(3和7)到三维(4 - 6),其中1以三种多晶型(α、β和γ)结晶。观察到H(n)dcbi从单齿到μ₅的七种配位模式,其中四种模式是首次发现。Cd(II)位点的配位几何结构从五配位三角双锥和四方锥、六配位八面体到七配位五角双锥不等。对Cd(II)配合物的合成条件和结构分析表明,溶剂和金属与配体的摩尔比对产物和H(n)dcbi(n = 0, 1, 2)的配位模式非常重要。对H(n)dcbi的配位模式和Cd(II)配合物结构的研究还表明,单去质子化的H₂dcbi通常以单齿咪唑 - N或N,O - 螯合模式配位,形成单核结构;双去质子化的Hdcbi以μ₂、μ₃或μ₄模式配位,生成一维或二维结构;三去质子化的dcbi可以以μ₅模式配位,形成三维结构。在制备6的过程中,通过乙腈的C - C键裂解原位形成氰化物,6采用罕见的μ₄ - kC,kC:kN,kN模式桥连四个Ag(I)离子。去除客体分子后,4的微孔三维骨架得以保留。化合物1 - 5在380 nm左右显示出强烈的紫光发射,初步归因于配体中心跃迁。
