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镧系元素容器对多位点受体的协同负载:一种制备有序发光金属聚合物的方法。

Cooperative loading of multisite receptors with lanthanide containers: an approach for organized luminescent metallopolymers.

作者信息

Babel Lucille, Guénée Laure, Besnard Céline, Eliseeva Svetlana V, Petoud Stéphane, Piguet Claude

机构信息

Department of Inorganic and Analytical Chemistry , University of Geneva , 30 quai E. Ansermet , CH-1211 Geneva 4 , Switzerland . Email:

Laboratory of Crystallography , University of Geneva , 24 quai E. Ansermet , CH-1211 Geneva 4 , Switzerland.

出版信息

Chem Sci. 2017 Nov 6;9(2):325-335. doi: 10.1039/c7sc03710d. eCollection 2018 Jan 14.

DOI:10.1039/c7sc03710d
PMID:29629101
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5872140/
Abstract

Metal-containing (bio)organic polymers are materials of continuously increasing importance for applications in energy storage and conversion, drug delivery, shape-memory items, supported catalysts, organic conductors and smart photonic devices. The embodiment of luminescent components provides a revolution in lighting and signaling with the ever-increasing development of polymeric light-emitting devices. Despite the unique properties expected from the introduction of optically and magnetically active lanthanides into organic polymers, the deficient control of the metal loading currently limits their design to empirical and poorly reproducible materials. We show here that the synthetic efforts required for producing soluble multi-site host systems are largely overcome by the virtue of reversible thermodynamics for mastering the metal loading with the help of only two parameters: (1) the affinity of the luminescent lanthanide container for a single binding site and (2) the cooperative effect which modulates the successive fixation of metallic units to adjacent sites. When unsymmetrical perfluorobenzene-trifluoroacetylacetonate co-ligands (pbta) are selected for balancing the charge of the trivalent lanthanide cations, Ln, in six-coordinate [Ln(pbta)] containers, the explored anti-cooperative complexation processes induce nearest-neighbor intermetallic interactions twice as large as thermal energy at room temperature ( = 2.5 kJ mol). These values have no precedent when using standard symmetrical containers and they pave the way for programming metal alternation in luminescent lanthanidopolymers.

摘要

含金属的(生物)有机聚合物在能量存储与转换、药物递送、形状记忆材料、负载型催化剂、有机导体及智能光子器件等应用领域正变得愈发重要。随着聚合物发光器件的不断发展,发光组件的应用给照明和信号领域带来了一场变革。尽管将具有光学和磁活性的镧系元素引入有机聚合物有望带来独特性能,但目前对金属负载量的控制不足,限制了其设计只能采用经验性且重现性差的材料。我们在此表明,借助可逆热力学,仅通过两个参数就能控制金属负载量,从而很大程度上克服了制备可溶性多位点主体体系所需的合成难题:(1)发光镧系元素容器对单个结合位点的亲和力;(2)调节金属单元相继固定到相邻位点的协同效应。当选择不对称的全氟苯 - 三氟乙酰丙酮共配体(pbta)来平衡六配位[Ln(pbta)]容器中三价镧系阳离子Ln的电荷时,所探究的反协同络合过程会引发近邻金属间相互作用,其强度在室温下是热能的两倍( = 2.5 kJ mol)。使用标准对称容器时这些值并无先例,它们为在发光镧系聚合物中编排金属交替奠定了基础。

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