低维金属有机框架:设计、探索和调整磁性结构的途径。

IF 1.3 3区 化学 Q3 CHEMISTRY, MULTIDISCIPLINARY
Stuart Calder, Raju Baral, C Charlotte Buchanan, Dustin A Gilbert, Rylan J Terry, Joseph W Kolis, Liurukara D Sanjeewa
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引用次数: 0

摘要

材料的磁性结构取决于对称性、磁性离子间交换相互作用的层次和局部各向异性。控制磁性相互作用的一个直接途径是在材料内部执行维度,从零维孤立磁性离子、一维(1D)自旋链、二维(2D)层到三维(3D)秩序。要设计出具有特定维度的材料来应对相关现象并非易事。虽然无机磁性材料领域已经取得了许多进展,但有机化合物为材料设计提供了独特的、潜在的更肥沃的土壤。特别是磁性金属有机框架(mMOFs),它将磁性与结构框架内有机连接体的非磁性特性功能结合在一起,可通过压力和磁场的轻微扰动进一步调整,从而诱发相变。本文研究了当磁性离子处于更广泛的三维晶体框架中的二维分层环境时,如何利用中子散射测量 mMOF 来直接确定磁性结构。水合甲酸盐的氚化形式 Co(DCOO)2-2D2O 是最早用中子衍射法研究的磁性 MOFs 之一,我们将以它为例重新进行研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Low-dimensional metal-organic frameworks: a pathway to design, explore and tune magnetic structures.

The magnetic structure adopted by a material relies on symmetry, the hierarchy of exchange interactions between magnetic ions and local anisotropy. A direct pathway to control the magnetic interactions is to enforce dimensionality within the material, from zero-dimensional isolated magnetic ions, one-dimensional (1D) spin-chains, two-dimensional (2D) layers to three-dimensional (3D) order. Being able to design a material with a specific dimensionality for the phenomena of interest is non-trivial. While many advances have been made in the area of inorganic magnetic materials, organic compounds offer distinct and potentially more fertile ground for material design. In particular magnetic metal-organic frameworks (mMOFs) combine magnetism with non-magnetic property functionality on the organic linkers within the structural framework, which can further be tuned with mild perturbations of pressure and field to induce phase transitions. Here, it is examined how neutron scattering measurements on mMOFs can be used to directly determine the magnetic structure when the magnetic ions are in a 2D layered environment within the wider 3D crystalline framework. The hydrated formate, in deuterated form, Co(DCOO)2·2D2O, which was one of the first magnetic MOFs to be investigated with neutron diffraction, is reinvestigated as an exemplar case.

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来源期刊
Acta crystallographica Section B, Structural science, crystal engineering and materials
Acta crystallographica Section B, Structural science, crystal engineering and materials CHEMISTRY, MULTIDISCIPLINARYCRYSTALLOGRAPH-CRYSTALLOGRAPHY
CiteScore
3.60
自引率
5.30%
发文量
0
期刊介绍: Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials publishes scientific articles related to the structural science of compounds and materials in the widest sense. Knowledge of the arrangements of atoms, including their temporal variations and dependencies on temperature and pressure, is often the key to understanding physical and chemical phenomena and is crucial for the design of new materials and supramolecular devices. Acta Crystallographica B is the forum for the publication of such contributions. Scientific developments based on experimental studies as well as those based on theoretical approaches, including crystal-structure prediction, structure-property relations and the use of databases of crystal structures, are published.
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