Self-assembly properties of zinc(ii) complexes with azo ligands grafted with dodecyl chains: towards supramolecular materials driven by coordination and hydrophobic effect†

IF 2.6 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY CrystEngComm Pub Date : 2024-10-18 DOI:10.1039/D4CE00983E
Kristina Gak Simić, Ivana Đorđević, Aleksandra Mašulović, Lidija Radovanović, Olivier Jeannin, Franck Camerel and Nemanja Trišović
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Abstract

Two zinc(II) complexes with azopyridine or azopyrimidine featuring dodecyl chains have been synthesized, crystallographically characterized and analyzed in the framework of quantum chemistry. In the mononuclear complex 1, the metal centre has a distorted octahedral geometry with two molecules of 2-(4-dodecyloxyphenylazo)pyrimidine connected in a bidentate fashion, while the remaining coordination sites are occupied by two monodentate nitrate anions. Considering the complex 2, a linear arrangement of three zinc atoms linked by acetate ions was observed. The central zinc atom, situated on the inversion center, is in a nearly perfect octahedral environment, while the outer symmetry-related zinc atoms have a distorted octahedral geometry and they coordinate to three acetate groups and to one molecule of 2-(4-dodecyloxyphenylazo)pyridine in a bidentate manner. In 1, enantiomers locally deracemize so that the coordinated units form homochiral ribbons, while the dodecyl chains from the neighbouring ribbons interdigitate to form layers of molecules. Compound 2 shows a comparable layered packing arrangement. Theoretical investigations of the supramolecular energetic landscape were conducted using density-functional theory (DFT) formalism, quantum theory of atoms in molecules (QTAIM), and natural bond orbital (NBO) computational tools. Quantifying the strength of polar and hydrophobic interactions revealed that H⋯H interactions, hydrophobic in nature, dominate the crystal arrangement of these molecules. The obtained results pave a pathway towards understanding self-organized molecular systems that reach the nano- and micrometer scales.

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十二烷基链接枝偶氮配体锌(ii)配合物的自组装特性:向配位和疏水效应驱动的超分子材料迈进†。
我们在量子化学框架内合成了两个锌(II)与具有十二烷基链的偶氮吡啶或偶氮嘧啶的配合物,并对其进行了晶体学表征和分析。在单核络合物 1 中,金属中心具有扭曲的八面体几何形状,两个 2-(4-十二烷氧基苯基偶氮)嘧啶分子以双齿方式连接,而其余配位位点则被两个单齿硝酸根阴离子占据。在复合物 2 中,观察到三个锌原子通过醋酸根离子呈线性排列。位于反转中心的中央锌原子处于近乎完美的八面体环境中,而与对称性相关的外部锌原子则具有扭曲的八面体几何形状,它们以双齿方式与三个醋酸基团和一个 2-(4-十二烷氧基苯基偶氮)吡啶分子配位。在化合物 1 中,对映体局部脱嵌合,使配位单元形成同手性带,而邻近带的十二烷基链相互嵌合形成分子层。化合物 2 显示出类似的分层堆积排列。我们利用密度函数理论(DFT)形式主义、分子中原子量子理论(QTAIM)和天然键轨道(NBO)计算工具对超分子能谱进行了理论研究。对极性和疏水相互作用的强度进行量化后发现,疏水性质的 H⋯H 相互作用在这些分子的晶体排列中占主导地位。这些结果为理解纳米和微米尺度的自组织分子系统铺平了道路。
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来源期刊
CrystEngComm
CrystEngComm 化学-化学综合
CiteScore
5.50
自引率
9.70%
发文量
747
审稿时长
1.7 months
期刊介绍: Design and understanding of solid-state and crystalline materials
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Back cover Back cover Back cover Synthesis of 3D composite materials based on ultrathin LDH nanowalls grown in situ on graphene surface and fast-response NO2 gas sensing performance at room temperature† Variations in crystals of flufenamic acid of its methyl and tert-butyl analogues as impurities as determined by partial dissolutions†
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