Yi-Fan Zhang, Ling-Ao Gui, Yan Peng, Zhao-Bo Hu, You Song
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引用次数: 0
Abstract
Magnetoelectric (ME) coupling refers to the interaction between electric and magnetic orders in materials. Based on ME coupling, the phenomenon that an external magnetic field induces electric polarization and an external electric field induces change in mangetization can be observed and is called the ME effect, such as magnetodielectric (MD), magnetoferroelectric (MF), magnetoresistence (MR) and electrically controlled magnetism. In recent years, ME effect has attracted increasing attention due to the wide range of potential applications in fields such as information storage, sensors, and spintronics. ME effect can be observed in both single-phase and composite systems but obtaining ME coupling in pure inorganic materials is extremely challenging. For example, in multiferroics with magnetism and electricity, the material must exhibit an magnetic ordered phase (ferromagnets or ferrimagnets) which coexists with the ferroelectric phase in the same temperature range. However, the materials containing both ordering phases within a single species are exceedingly rare, and those capable of producing coupling the two are even scarcer. MD materials are relatively easy to obtain because they are not constrained by polar point groups in their structure. With advancements in science and technology, new materials with potential ME coupling are increasingly being identified, particularly in the field of molecular materials. Molecular materials, due to their ease of design and synthesis, can not only achieve the regulation of magnetic field on polarization, but also complete the control of electric field on magnetism. This perspective paper briefly reviews recent research progress on the ME effect in molecular materials, focusing on three aspects: magnetodielectrics, magnetoferroelectrics, and electronically controlled magnetism. Typical complexes exhibiting ME effects in these three categories are analyzed and summarized.
磁电(ME)耦合是指材料中电序和磁序之间的相互作用。基于磁电耦合,可以观察到外磁场诱导电极化,外电场诱导磁极化变化的现象,称为磁电效应,如磁介电(MD)、磁铁电(MF)、磁电阻(MR)和电控磁。近年来,ME 效应因其在信息存储、传感器和自旋电子学等领域的广泛潜在应用而日益受到关注。在单相和复合系统中都能观察到 ME 效应,但在纯无机材料中获得 ME 耦合却极具挑战性。例如,在具有磁性和电性的多铁物中,材料必须表现出磁性有序相(铁磁体或铁磁体),该有序相与铁电相在同一温度范围内共存。然而,在单一物种中同时包含这两种有序相的材料极为罕见,而能够产生这两种有序相耦合的材料则更为稀少。MD 材料相对容易获得,因为它们的结构不受极性点基团的限制。随着科学技术的进步,具有 ME 耦合潜力的新材料越来越多地被发现,特别是在分子材料领域。分子材料由于易于设计和合成,不仅能实现磁场对极化的调节,还能完成电场对磁性的控制。本视角论文简要回顾了分子材料中 ME 效应的最新研究进展,重点关注磁介电、磁铁电和电控磁三个方面。本文分析并总结了这三类材料中表现出 ME 效应的典型复合物。
期刊介绍:
Dalton Transactions is a journal for all areas of inorganic chemistry, which encompasses the organometallic, bioinorganic and materials chemistry of the elements, with applications including synthesis, catalysis, energy conversion/storage, electrical devices and medicine. Dalton Transactions welcomes high-quality, original submissions in all of these areas and more, where the advancement of knowledge in inorganic chemistry is significant.
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