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新型咪唑鎓(+)盐[Cu(Him)]{Cu(Him)[Cu(μ-EDTA)(Him)]}·6H₂O(1)中线性三核阴离子的磁性分离——[Cu(Him)]{Cu(Him)[Cu(μ-EDTA)(Him)]}·2H₂O(2)的晶体结构、热学、光谱和磁性性质及密度泛函理论计算的比较研究

Magnetic Isolation of the Linear Trinuclear Anion in [Cu(Him)] {Cu(Him)[Cu(μ-EDTA)(Him)]}·6HO (1) as the Novel Imidazolium(+) Salt (Him)[Cu(Him){(µ-EDTA)Cu(Him)}]·2HO (2)-A Comparative Look to Their Crystal Structures, Thermal, Spectral and Magnetic Properties and DFT Calculations.

作者信息

Belmont-Sánchez Jeannette Carolina, Choquesillo-Lazarte Duane, Frontera Antonio, Lezama Luis, Castiñeiras Alfonso, Niclós-Gutiérrez Juan

机构信息

Department of Inorganic Chemistry, Faculty of Pharmacy, University of Granada, 18071 Granada, Spain.

Laboratorio de Estudios Cristalográficos (LEC), IACT, CSIC-Universidad de Granada, Av. de las Palmeras 4, 18100 Armilla, Spain.

出版信息

Int J Mol Sci. 2024 Dec 6;25(23):13130. doi: 10.3390/ijms252313130.

DOI:10.3390/ijms252313130
PMID:39684840
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11641978/
Abstract

Inspired by the reported crystal structure of compound , we aimed to synthesize and determine the structure of compound , where two imidazolium (Him) ions serve as diamagnetic countercations. Here, we report the thermal stabilities, FT-IR, visible, and RSE spectra, as well as the magnetic properties of both compounds. In these structures, µ-EDTA acts as a pentadentate chelator for both terminal Cu centers within the centrosymmetric linear trinuclear anion. The Cu(µ-EDTA) chelates bind to the central Cu(Him) unit in subtly different ways: in compound , µ-EDTA has a free acetate arm and binds the central Cu(II) center through a syn,anti-carboxylate group. In contrast, in compound , the non-chelating acetate arm serves as a monodentate O-donor to the central Cu(II) atom, increasing the Cu(terminal)···Cu(central) distance from 6.08 Å in to 6.80 Å in . Additionally, pairs of Him ions in compound display antiparallel π-stacking interactions. We conclude that the Him counterions in compound enable the magnetic isolation of the nearly identical trinuclear anion present in both compounds. DFT calculations further support the role of different interactions in stabilizing each crystal structure. In compound , dominant contributions from N-H···O hydrogen bonds and π-stacking interactions are accompanied by other, less conventional interactions, such as multiple C-H···O contacts and an O···CO(π-hole) interaction within the trinuclear anion.

摘要

受所报道的化合物晶体结构的启发,我们旨在合成并确定化合物的结构,其中两个咪唑鎓(Him)离子作为抗磁性抗衡阳离子。在此,我们报告了这两种化合物的热稳定性、傅里叶变换红外光谱(FT-IR)、可见光谱和拉曼光谱(RSE)以及磁性。在这些结构中,µ-乙二胺四乙酸(µ-EDTA)作为中心对称线性三核阴离子中两个末端铜中心的五齿螯合剂。Cu(µ-EDTA)螯合物以略有不同的方式与中心Cu(Him)单元结合:在化合物中,µ-EDTA有一个游离的乙酸酯臂,并通过顺式、反式羧酸盐基团与中心Cu(II)中心结合。相比之下,在化合物中,非螯合的乙酸酯臂作为中心Cu(II)原子的单齿氧供体,使Cu(末端)···Cu(中心)的距离从化合物中的6.08 Å增加到化合物中的6.80 Å。此外,化合物中的Him离子对表现出反平行的π-堆积相互作用。我们得出结论,化合物中的Him抗衡离子能够使两种化合物中存在的几乎相同的三核阴离子实现磁隔离。密度泛函理论(DFT)计算进一步支持了不同相互作用在稳定每个晶体结构中的作用。在化合物中,N-H···O氢键和π-堆积相互作用的主要贡献伴随着其他不太常见的相互作用,如三核阴离子内的多个C-H···O接触和O···CO(π-空穴)相互作用。

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