Company Anna, Jee Joo-Eun, Ribas Xavi, Lopez-Valbuena Josep Maria, Gómez Laura, Corbella Montserrat, Llobet Antoni, Mahía José, Benet-Buchholz Jordi, Costas Miquel, van Eldik Rudi
Departament de Química, Universitat de Girona, Campus de Montilivi, Girona, Spain.
Inorg Chem. 2007 Oct 29;46(22):9098-110. doi: 10.1021/ic700692t. Epub 2007 Oct 3.
A study of the reversible CO2 fixation by a series of macrocyclic dicopper complexes is described. The dicopper macrocyclic complexes Cu2(OH)2(Me2p)2, 1(CF3SO3)2, and Cu2(mu-OH)2(Me2m)2, 2(CF3SO3)2, (Scheme 1) containing terminally bound and bridging hydroxide ligands, respectively, promote reversible inter- and intramolecular CO2 fixation that results in the formation of the carbonate complexes {Cu2(Me2p)}2(mu-CO3)24, 4(CF3SO3)4, and Cu2(mu-CO3)(Me2m)2, 5(CF3SO3)2. Under a N2 atmosphere the complexes evolve CO2 and revert to the starting hydroxo complexes 1(CF3SO3)2 and 2(CF3SO3)2, a reaction the rate of which linearly depends on [H2O]. In the presence of water, attempts to crystallize 5(CF3SO3)2 afford {Cu2(Me2m)(H2O)}2(mu-CO3)24, 6(CF3SO3)4, which appears to rapidly convert to 5(CF3SO3)2 in acetonitrile solution. [Cu2(OH)2(H3m)]2+, 7, which contains a larger macrocyclic ligand, irreversibly reacts with atmospheric CO2 to generate cagelike {Cu2(H3m)}2(mu-CO3)24, 8(ClO4)4. However, addition of 1 equiv of HClO4 per Cu generates [Cu2(H3m)(CH3CN)4]4+ (3), and subsequent addition of Et3N under air reassembles 8. The carbonate complexes 4(CF3SO3)4, 5(CF3SO3)2, 6(CF3SO3)4, and 8(ClO4)4 have been characterized in the solid state by X-ray crystallography. This analysis reveals that 4(CF3SO3)4, 6(CF3SO3)4, and 8(ClO4)4 consist of self-assembled molecular boxes containing two macrocyclic dicopper complexes, bridged by CO32- ligands. The bridging mode of the carbonate ligand is anti-anti-mu-eta1:eta1 in 4(CF3SO3)4, anti-anti-mu-eta2:eta1 in 6(CF3SO3)4 and anti-anti-mu-eta2:eta2 in 5(CF3SO3)2 and 8(ClO4)4. Magnetic susceptibility measurements on 4(CF3SO3)4, 6(CF3SO3)4, and 8(ClO4)4 indicate that the carbonate ligands mediate antiferromagnetic coupling between each pair of bridged CuII ions (J = -23.1, -108.3, and -163.4 cm-1, respectively, H = -JS1S2). Detailed kinetic analyses of the reaction between carbon dioxide and the macrocyclic complexes 1(CF3SO3)2 and 2(CF3SO3)2 suggest that it is actually hydrogen carbonate formed in aqueous solution on dissolving CO2 that is responsible for the observed formation of the different carbonate complexes controlled by the binding mode of the hydroxy ligands. This study shows that CO2 fixation can be used as an on/off switch for the reversible self-assembly of supramolecular structures based on macrocyclic dicopper complexes.
本文描述了一系列大环二铜配合物对二氧化碳的可逆固定作用的研究。二铜大环配合物Cu2(OH)2(Me2p)2、1(CF3SO3)2和Cu2(μ-OH)2(Me2m)2、2(CF3SO3)2(方案1)分别含有末端配位和桥联的氢氧根配体,它们促进了分子间和分子内二氧化碳的可逆固定,从而形成碳酸根配合物{Cu2(Me2p)}2(μ-CO3)24、4(CF3SO3)4和Cu2(μ-CO3)(Me2m)2、5(CF3SO3)2。在氮气气氛下,这些配合物会释放出二氧化碳并还原为起始的羟基配合物1(CF3SO3)2和2(CF3SO3)2,该反应速率与[H2O]呈线性关系。在有水存在的情况下,尝试结晶5(CF3SO3)2得到{Cu2(Me2m)(H2O)}2(μ-CO3)24、6(CF3SO3)4,它在乙腈溶液中似乎会迅速转化为5(CF3SO3)2。[Cu2(OH)2(H3m)]2+、7含有更大的大环配体,它与大气中的二氧化碳发生不可逆反应,生成笼状的{Cu2(H3m)}2(μ-CO3)24、8(ClO4)4。然而,每摩尔铜加入1当量的高氯酸会生成[Cu2(H3m)(CH3CN)4]4+(3),随后在空气中加入三乙胺可重新组装得到8。碳酸根配合物4(CF3SO3)4、5(CF3SO3)2、6(CF3SO3)4和8(ClO4)4已通过X射线晶体学对其固态进行了表征。该分析表明,4(CF3SO3)4、6(CF3SO3)4和8(ClO4)4由自组装的分子盒组成,其中包含两个由CO32-配体桥联的大环二铜配合物。碳酸根配体的桥联模式在4(CF3SO3)4中为反-反-μ-η1:η1,在6(CF3SO3)4中为反-反-μ-η2:η1,在5(CF3SO3)2和8(ClO4)4中为反-反-μ-η2:η2。对4(CF3SO3)4、6(CF3SO3)4和8(ClO4)4的磁化率测量表明,碳酸根配体介导了每对桥联CuII离子之间的反铁磁耦合(J分别为-23.1、-108.3和-163.4 cm-1,H = -JS1S2)。对二氧化碳与大环配合物1(CF3SO3)2和2(CF3SO3)2之间反应的详细动力学分析表明,实际上是溶解二氧化碳时在水溶液中形成的碳酸氢根导致了观察到的由羟基配体的结合模式控制的不同碳酸根配合物的形成。这项研究表明,二氧化碳固定可作为基于大环二铜配合物的超分子结构可逆自组装的开/关开关。
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