氯双铋酸盐中无机亚结构的畸变(III)

M. Bujak
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引用次数: 1

摘要

氯化铋(III)与N,N-二甲基乙烷-1,2-二铵,[(CH3) 2nhh (CH2)2NH3]2+和N,N,N,N ',N ' -四甲基胍,[NH2C{N(CH3)2}2]+的有机和无机反应物的摩尔比变化导致四种不同的产物,即三(N,N-二甲基乙烷-1,2-二铵)二[六氯二甲基乙烷(III)], [(CH3) 2nhh (CH2)2NH3]3[BiCl6]2(1),链-聚[N,N-二甲基乙烷-1,2-二铵][[四氯二甲基乙烷(III)]-μ-氯]],{[(CH3) 2nhh (CH2)2NH3][BiCl5]} n(2)、tris(n, n, n ', n ' -四甲基胍)3 -μ-氯-双[三氯双胍(III)]、[NH2C{n (CH3)2}2]3[Bi2Cl9](3)和catena-poly[n, n, n ', n ' -四甲基胍[[二氯双胍(III)]-二-μ-氯]]、{[NH2C{n (CH3)2}2][BiCl4]} n(4)。杂化晶体1-4含有较大但不同的有机阳离子,由四个不同的阴离子亚结构组成。它们是由1中的[BiCl6]3−八面体、3中的[Bi2Cl9]3−单元、2中的{[BiCl5]2−}n共聚链和4中的{[BiCl4]−}n共聚链组成的。1-4中单个[BiCl6]3−多面体所显示的畸变与阴离子亚结构和有机结构之间的内在相互作用有关。无机子结构相互作用,即N/ C-H…Cl氢键。第一个因素更强,这在实验确定的几何畸变参数和计算的孤立八面体1与更复杂的无机子结构2-4的畸变参数的比较中是明显的。N-H的形成…Cl氢键,在它们的数量和强度方面,有利于1和3含有相对容易接近的孤立的[BiCl6]3−和[Bi2Cl9]3−单元的氢键受体。剑桥结构数据库的一项调查证实了不同因素在无机阴离子的几何变化中所起的作用,支持了无机阴离子在无机亚结构中偏离规则性的研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Understanding distortions of inorganic substructures in chloridobismuthates(III)
The molar ratio variations of organic and inorganic reactants of chloridobismuthates(III) with N,N-dimethylethane-1,2-diammonium, [(CH3)2NH(CH2)2NH3]2+, and N,N,N′,N′-tetramethylguanidinium, [NH2C{N(CH3)2}2]+, cations lead to the formation of four different products, namely, tris(N,N-dimethylethane-1,2-diammonium) bis[hexachloridobismuthate(III)], [(CH3)2NH(CH2)2NH3]3[BiCl6]2 (1), catena-poly[N,N-dimethylethane-1,2-diammonium [[tetrachloridobismuthate(III)]-μ-chlorido]], {[(CH3)2NH(CH2)2NH3][BiCl5]} n (2), tris(N,N,N′,N′-tetramethylguanidinium) tri-μ-chlorido-bis[trichloridobismuthate(III)], [NH2C{N(CH3)2}2]3[Bi2Cl9] (3), and catena-poly[N,N,N′,N′-tetramethylguanidinium [[dichloridobismuthate(III)]-di-μ-chlorido]], {[NH2C{N(CH3)2}2][BiCl4]} n (4). The hybrid crystals 1–4, containing relatively large but different organic cations, are composed of four distinct anionic substructures. They are built up from isolated [BiCl6]3− octahedra in 1, from face-sharing bioctahedral [Bi2Cl9]3− units in 3, from polymeric corner-sharing {[BiCl5]2−} n chains in 2 and from edge-sharing {[BiCl4]−} n chains in 4. The distortions shown by the single [BiCl6]3− polyhedra in 1–4 are associated with intrinsic interactions within the anionic substructures and the organic...inorganic substructures interactions, namely, N/C—H...Cl hydrogen bonds. The first factor is the stronger, which is evident in comparison of the experimentally determined geometrical and calculated distortion parameters for the isolated octahedron in 1 to the more complex inorganic substructures in 2–4. The formation of N—H...Cl hydrogen bonds, in terms of their number and strength, is favoured for 1 and 3 containing relatively easily accessed hydrogen-bond acceptors of isolated [BiCl6]3− and [Bi2Cl9]3− units. The studies of the deviations from regularity of the [BiCl6]3− octahedra within inorganic substructures were supported by a survey of the Cambridge Structural Database, which confirmed the role played by different factors in the variations in geometry of the inorganic anions.
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