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从{铁-镧系}蝴蝶的视角:基于3d-4f的配位簇合物中协同作用的磁学益处与挑战

From the {Fe Ln } Butterfly's Perspective: the Magnetic Benefits and Challenges of Cooperativity within 3 d-4 f Based Coordination Clusters.

作者信息

Peng Yan, Kaemmerer Hagen, Powell Annie K

机构信息

Institute of Inorganic Chemistry, Karlsruhe Institute of Technology, Engesserstr. 15, 76131, Karlsruhe, Germany.

Institute for Nanotechnology (INT), Karlsruhe Institute of Technology, Hermann-von-Helmholtz-Platz 1, 76344, Eggenstein-Leopoldshafen, Germany.

出版信息

Chemistry. 2021 Nov 2;27(61):15043-15065. doi: 10.1002/chem.202102962. Epub 2021 Oct 19.

DOI:10.1002/chem.202102962
PMID:34582064
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8597143/
Abstract

In this Review we discuss the tuning handles which can be used to steer the magnetic properties of Fe -4 f "butterfly" compounds. The majority of presented compounds were produced in the context of project A3 "Di- to tetranuclear compounds incorporating highly anisotropic paramagnetic metal ions" within the SFB/TRR88 "3MET". These contain {Fe Ln } cores encapsulated in ligand shells which are easy to tune in a "test-bed" system. We identify the following advantages and variables in such systems: (i) the complexes are structurally simple usually with one crystallographically independent Fe and Ln , respectively. This simplifies theory and anaylsis; (ii) choosing Fe allows Fe Mössbauer spectroscopy to be used as an additional technique which can give information about oxidation levels and spin states, local moments at the iron nuclei and spin-relaxation and, more importantly, about the anisotropy not only of the studied isotope, but also of elements interacting with this isotope; (iii) isostructural analogues with all the available (i. e. not Pm) 4 f ions can be synthesised, enabling a systematic survey of the influence of the 4 f ion on the electronic structure; (iv) this cluster type is obtained by reacting Fe O(O CR) (L) (X=anion, L=solvent such as H O, py) with an ethanolamine-based ligand L' and lanthanide salts. This allows to study analogues of [Fe Ln (μ -OH) (L') (O CR) ] using the appropriate iron trinuclear starting materials. (v) the organic main ligand can be readily functionalised, facilitating a systematic investigation of the effect of organic substituents on the ligands on the magnetic properties of the complexes. We describe and discuss 34 {M Ln } (M=Fe or in one case Al) butterfly compounds which have been reported up to 2020. The analysis of these gives perspectives for designing new SMM systems with specific electronic and magnetic signatures.

摘要

在本综述中,我们讨论了可用于调控Fe - 4f“蝴蝶”化合物磁性的调节手段。所介绍的大多数化合物是在SFB/TRR88“3MET”项目的A3“包含高各向异性顺磁性金属离子的双核至四核化合物”背景下制备的。这些化合物包含封装在配体壳层中的{Fe Ln}核,在“测试平台”系统中易于调节。我们确定了此类系统的以下优点和变量:(i) 配合物结构简单,通常分别具有一个晶体学独立的Fe和Ln。这简化了理论和分析;(ii) 选择Fe使得Fe穆斯堡尔谱能够用作一种额外的技术,该技术可以提供有关氧化态和自旋态、铁原子核处的局域磁矩和自旋弛豫的信息,更重要的是,不仅能提供有关所研究同位素的各向异性信息,还能提供与该同位素相互作用的元素的各向异性信息;(iii) 可以合成与所有可用的(即不包括Pm)4f离子的同构类似物,从而能够系统地研究4f离子对电子结构的影响;(iv) 这种簇类型是通过使Fe O(O CR) (L) (X = 阴离子,L = 溶剂如H O、py)与基于乙醇胺的配体L'和镧系盐反应得到的。这使得能够使用合适的铁三核起始材料研究[Fe Ln (μ -OH) (L') (O CR) ]的类似物。(v) 有机主配体可以很容易地进行功能化,便于系统研究配体上有机取代基对配合物磁性的影响。我们描述并讨论了截至2020年已报道的34种{M Ln}(M = Fe或在一种情况下为Al)蝴蝶化合物。对这些化合物的分析为设计具有特定电子和磁性特征的新型单分子磁体系统提供了思路。

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4
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