Crystal Structure of μ-Phenoxo-μ-benzoate-bridged Dinuclear Fe(II) Complex with a Dinucleating Ligand Having a Sterically Bulky Imidazolyl Group
Y. Yasuda, H. Furutachi, Yosuke Hayashi, Kaname Ishizaki, S. Fujinami, Shigehisa Akine, Masatatsu Suzuki, S. Nagatomo, T. Kitagawa
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引用次数: 1
Abstract
The end-off type compartmental ligands, having a phenolic and alcoholic oxygen as an endogenous bridge, have been used for modeling bimetallic active sites of metalloprotains,1–4 such as hemerythrin (Hr)5 and methane monooxygenase (MMO).6 We have demonstrated that the thermal stability of (μ-peroxo) diiron(III) complexes and the oxygenation-deoxygenation reversibility are highly dependent on the nature of the end-off type compartmental ligands.4,7–11 Previously, we reported the crystal structure of a (μ-peroxo)diiron(III) complex, [Fe2(Phbimp)(PhCO2)(O2)], with a dinucleating ligand (Ph-bimp) bearing a sterically bulky imidazolyl group,8 which was obtained in a reversible reaction of the corresponding diiron(II) precursor complex, [Fe2(Ph-bimp)(PhCO2)](BF4)2·3H2O, with dioxygen in acetonitrile at ambient temperature. In this paper, we report details of the crystal structure of the diiron(II) precursor complex [Fe2(Ph-bimp)(PhCO2)(CH3CN)](BF4)2·2CH3CN·3CH3CH2OH (1) (Fig. 1). A single crystal of [Fe2(Ph-bimp)(PhCO2)(CH3CN)](BF4)2· 2CH3CN·3CH3CH2OH (1) suitable for X-ray crystallography was obtained by recrystallization of [Fe2(Ph-bimp)(PhCO2)](BF4)2·3H2O from a mixture of acetonitrile/ethanol at ambient temperature under N2. It was picked up on a hand-made cold copper plate mounted inside a liquid N2 Dewar vessel and mounted on a glass rod at –80°C. X-ray diffraction measurements were made on a Rigaku CCD Mercury diffractometer with graphite monochromated Mo Kα radiation at 108 K. The structure was solved by a direct method (SIR 92)12 and expanded using a Fourier technique. The structure was refined by a fullmatrix least-squares method by using SHELXL 201413 (Yadokari-XG).14 All non-hydrogen atoms were refined with anisotropic displacement parameters (ADP) and all hydrogen atoms were included using a riding model. The occupancy factors were also refined for the two BF4 anions, one acetonitrile molecule, and three ethanol molecules, which were disordered over two or three orientations. Distance/ADP restraints were applied to the disordered atoms in the anions and solvents. The crystal data is summarized in Table 1. The molecular structure of complex cation [Fe2(Ph-bimp)(PhCO2)(CH3CN)] of 1 is shown in Fig. 2. Selected bond distances (Å) and angles (°) are given in Table 2. The diiron(II) center is doubly bridged by phenoxide oxygen of Ph-bimp and benzoate oxygens, as found for closely related diiron(II) complexes: [Fe2(Ph-tidp)(PhCO2)] (2) (Ph-tidp = N,N,N′,N′tetrakis(1-methyl-4,5-diphenyl-2-imidazolyl)methyl-1,3-diamino2-propanolate),9 [Fe2(L)(PhCO2)] (3) (LPh4 = N,N,N′,N′tetrakis(1-methyl-2-phenyl-4-imidazolyl)methyl-1,3-diamino2-propanolate),10 and [Fe2(N-Et-HPTB)(PhCO2)] (4) (N-EtHPTB = N,N,N′,N′-tetrakis(1-ethyl-2-benzimidazolyl)methyl1,3-diamino-2-propanolate).15 The two iron atoms in 1 have different coordination geometries. The five-coordinate iron 2019 © The Japan Society for Analytical Chemistry
μ-苯氧基-μ-苯甲酸偶联双核咪唑基配合物的晶体结构
具有酚氧和醇氧作为内源性桥的末端型隔室配体已用于模拟金属蛋白的双金属活性位点,1–4,如赤藓红素(Hr)5和甲烷单加氧酶(MMO)。6我们已经证明,(μ-过氧)二亚胺(III)复合物的热稳定性和氧化-脱氧可逆性高度依赖于末端型隔室配体的性质。4,7–11之前,我们报道了(μ-过氧化)二亚胺复合物的晶体结构[Fe2(Phbimp)(PhCO2)(O2)],带有空间大体积咪唑基的双核配体(Ph-bimp),8在环境温度下,通过相应的二亚胺(II)前体络合物[Fe2(Ph-bimp)(PhCO2)](BF4)2·3H2O与乙腈中的双氧的可逆反应获得。在本文中,我们报道了二铁(II)前体配合物[Fe2(Ph-bimp)(PhCO2)(CH3CN)](BF4)2·2CH3CN·3CH3CH2OH(1)的晶体结构细节(图1)。室温下,在N2气氛下,由乙腈/乙醇混合物重结晶[Fe2(Ph-bimp)(PhCO2)](BF4)2·3H2O,得到了适合X射线晶体学的[Fe2(PhCO2)(CH3CN)](高炉煤气)2·2CH3CN·3CH3CH2OH(1)单晶。它是在安装在液态N2杜瓦容器内的手工冷铜板上收集的,并安装在-80°C的玻璃棒上。在Rigaku CCD Mercury衍射仪上用石墨单色Mo Kα辐射在108K下进行X射线衍射测量。通过直接方法(SIR 92)12求解结构,并使用傅立叶技术进行扩展。使用SHELXL 201413(Yadokari XG)通过全矩阵最小二乘法对结构进行细化。14使用各向异性位移参数(ADP)对所有非氢原子进行细化,并使用骑行模型将所有氢原子包括在内。还对两个BF4阴离子、一个乙腈分子和三个乙醇分子的占据因子进行了细化,它们在两个或三个方向上是无序的。对阴离子和溶剂中的无序原子施加距离/ADP约束。晶体数据汇总在表1中。1的配合阳离子[Fe2(Ph-bimp)(PhCO2)(CH3CN)]的分子结构如图所示。2。表2中给出了选定的键距(Å)和角度(°)。二铁(II)中心由Ph-bimp的苯氧基氧和苯甲酸氧双重桥接,如密切相关的二铁(Ⅱ)配合物:[Fe2(Ph-tidp)(PhCO2)](2)(Ph-tip=N,N,N′,N′四(1-甲基-4,5-二苯基-2-咪唑基)甲基-1,3-二氨基-2-丙醇),9[Fe2(L)(Ph二氧化碳)](3)(LPh4=N,N,N′、N′四个(1-甲基-2-苯基-4-咪唑基)-甲基-1,3二氨基-2-丙酸酯),10和[Fe2(N-Et-HPTB)(PhCO2)](4)(N-EtHPTB=N,N,N′,N′-四(1-乙基-2-苯并咪唑基)甲基1,3-二氨基-2-丙醇)。五配位铁2019©日本分析化学学会
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