一种可变的银 - 铬 - 草酸盐通道晶格:[M(x)Ag(0.5)(-)(x)(H₂O)₃]@[Ag₂.₅Cr(C₂O₄)₃],M = K、Cs、Ag
A variable Ag-Cr-Oxalate channel lattice: [M(x)Ag(0.5)(-)(x)(H(2)O)(3)]@[Ag(2.5)Cr(C(2)O(4))(3)], M = K, Cs, Ag.
作者信息
Dean Philip A W, Craig Don, Dance Ian, Russell Vanessa, Scudder Marcia
机构信息
Department of Chemistry, University of Western Ontario, London, Ontario N6A 5B7, Canada.
出版信息
Inorg Chem. 2004 Jan 26;43(2):443-9. doi: 10.1021/ic034988k.
Reaction of aqueous AgNO(3) with aqueous M(3)[Cr(ox)(3)] in >or=3:1 molar ratio causes the rapid growth of large, cherry-black, light-stable crystals which are not Ag(3)[Cr(ox)(3)], but [M(0.5)(H(2)O)(3)]@[Ag(2.5)Cr(ox)(3)] (ox(2)(-) = oxalate, C(2)O(4)(2)(-); M = Na, K, Cs, Ag, or mixtures of Ag and a group 1 element). The structure of these crystals contains an invariant channeled framework, with composition Ag(2.5)Cr(ox)(3)(0.5), constructed with [Cr(ox)(3)] coordination units linked by Ag atoms through centrosymmetric Cr-O(2)C(2)O(2)-Ag double bridges. The framework composition Ag(2.5)Cr(ox)(3)(0.5) occurs because one Ag is located on a 2-fold axis. Within the channels there is a well-defined and ordered set of six water molecules, strongly hydrogen bonded to each other and some of the oxalate O atoms. This invariant channel plus water structure accommodates group 1 cations, and/or Ag cations, in different locations and in variable proportions, but always coordinated by channel water and some oxalate O atoms. The general formulation of these crystals is therefore [M(x)Ag(0.5-x)(H(2)O)(3)]@[Ag(2.5)Cr(ox)(3)]. Five different crystals with this structure are reported, with compositions 1 Ag(0.5)Ag(2.5)Cr(ox)(3)(3), 2 Cs(0.19)Ag(0.31)Ag(2.5)Cr(ox)(3)(3), 3 K(0.28)Ag(0.22)Ag(2.5)Cr(ox)(3)(3), 4 Cs(0.41)Ag(0.09)Ag(2.5)Cr(ox)(3)(3), and 5 Cs(0.43)Ag(0.07) Ag(2.5)Cr(ox)(3)(3). All crystallize in space group C2/c, with a approximately 18.4, b approximately 14.6, c approximately 12.3 A, beta approximately 113 degrees. Pure Ag(3)Cr(ox)(3)(3), which has the same crystal structure (1), was obtained from water by treating Li(3)[Cr(ox)(3)] with excess AgNO(3). Complete dehydration of all of these compounds occurs between 30 and 100 degrees C, with loss of diffraction, but rehydration by exposure to H(2)O(g) at ambient temperature leads to recovery of the original diffraction pattern. In single crystals, this reversible dehydration-hydration occurs without visually evident crystal change, but with loss of mechanical strength. We postulate a general mechanism for transport of water molecules along the channels, associated with local partial collapses of the channel framework, with concomitant bending but little breaking of the host Ag-O and Cr-O bonds, which is readily reversed.
硝酸银水溶液与摩尔比≥3:1的M₃[Cr(ox)₃]水溶液反应,会迅速生成大的、樱桃黑色、光稳定的晶体,这些晶体不是Ag₃[Cr(ox)₃],而是[M₀.₅(H₂O)₃]@[Ag₂.₅Cr(ox)₃](ox²⁻ = 草酸根,C₂O₄²⁻;M = Na、K、Cs、Ag或Ag与第1族元素的混合物)。这些晶体的结构包含一个不变的通道框架,其组成为[[Ag₂.₅Cr(ox)₃]⁻⁰.₅]∞,由[Cr(ox)₃]配位单元通过中心对称的[Cr - O₂C₂O₂ - Ag]₂双桥与Ag原子相连构成。框架组成[Ag₂.₅Cr(ox)₃]⁻⁰.₅的出现是因为一个Ag位于二重轴上。在通道内有一组明确且有序的六个水分子,它们彼此之间以及与一些草酸根O原子形成强氢键。这种不变的通道加水结构在不同位置以不同比例容纳第1族阳离子和/或Ag阳离子,但总是由通道水和一些草酸根O原子配位。因此,这些晶体的一般化学式为[MₓAg₀.₅₋ₓ(H₂O)₃]@[Ag₂.₅Cr(ox)₃]。报道了具有这种结构的五种不同晶体,其组成分别为1 Ag₀.₅Ag₂.₅Cr(ox)₃₃、2 Cs₀.₁₉Ag₀.₃₁Ag₂.₅Cr(ox)₃₃、3 K₀.₂₈Ag₀.₂₂Ag₂.₅Cr(ox)₃₃、4 Cs₀.₄₁Ag₀.₀₉Ag₂.₅Cr(ox)₃₃和5 Cs₀.₄₃Ag₀.₀₇Ag₂.₅Cr(ox)₃₃。它们都结晶于空间群C2/c,a约为18.4 Å,b约为14.6 Å,c约为12.3 Å,β约为113°。通过用过量硝酸银处理Li₃[Cr(ox)₃]从水中得到了具有相同晶体结构(1)的纯Ag₃Cr(ox)₃₃。所有这些化合物在30至100℃之间完全脱水,伴随衍射消失,但在室温下暴露于H₂O(g)进行再水化会导致原始衍射图案恢复。在单晶中,这种可逆的脱水 - 水化过程在视觉上晶体无明显变化,但机械强度会损失。我们推测了水分子沿通道传输的一般机制,这与通道框架的局部部分坍塌有关,同时主体的Ag - O和Cr - O键会弯曲但很少断裂,且这种过程很容易逆转。
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