Multiferroic materials and magnetoelectric physics: symmetry, entanglement, excitation, and topology

IF 35 1区 物理与天体物理 Q1 PHYSICS, CONDENSED MATTER
S. Dong, Jun-ming Liu, S. Cheong, Z. Ren
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引用次数: 588

Abstract

Multiferroics are those materials with more than one ferroic order, and magnetoelectricity refers to the mutual coupling between magnetism (spins and/or magnetic field) and electricity (electric dipoles and/or electric field). In spite of the long research history in the whole twentieth century, the discipline of multiferroicity has never been so highly active as that in the first decade of the twenty-first century, and it has become one of the hottest disciplines of condensed matter physics and materials science. A series of milestones and steady progress in the past decade have enabled our understanding of multiferroic physics substantially comprehensive and profound, which is further pushing forward the research frontier of this exciting area. The availability of more multiferroic materials and improved magnetoelectric performance are approaching to make the applications within reach. While seminal review articles covering the major progress before 2010 are available, an updated review addressing the new achievements since that time becomes imperative. In this review, following a concise outline of the basic knowledge of multiferroicity and magnetoelectricity, we summarize the important research activities on multiferroics, especially magnetoelectricity and related physics in the last six years. We consider not only single-phase multiferroics but also multiferroic heterostructures. We address the physical mechanisms regarding magnetoelectric coupling so that the backbone of this divergent discipline can be highlighted. A series of issues on lattice symmetry, magnetic ordering, ferroelectricity generation, electromagnon excitations, multiferroic domain structure and domain wall dynamics, and interfacial coupling in multiferroic heterostructures, will be revisited in an updated framework of physics. In addition, several emergent phenomena and related physics, including magnetic skyrmions and generic topological structures associated with magnetoelectricity will be discussed. The review is ended with a set of prospectives and forward-looking conclusions, which may inevitably reflect the authors' biased opinions but are certainly critical.
多铁性材料与磁电物理:对称、纠缠、激发与拓扑
多铁性材料是指具有一个以上铁序的材料,磁电是指磁(自旋和/或磁场)和电(电偶极子和/或电场)之间的相互耦合。在整个二十世纪,多铁性学科有着悠久的研究历史,但在二十一世纪的头十年里,多铁性学科表现出前所未有的活跃,已成为凝聚态物理和材料科学中最热门的学科之一。在过去的十年中,一系列里程碑式的进展使我们对多铁物理的理解更加全面和深刻,这进一步推动了这一激动人心的领域的研究前沿。更多的多铁性材料的可用性和改进的磁电性能正在接近使应用成为可能。虽然有涵盖2010年之前主要进展的开创性评论文章,但一份针对2010年以来新成就的最新评论变得势在必行。本文在简要介绍多铁性和磁电的基本知识的基础上,总结了近六年来多铁性,特别是磁电及其相关物理学的重要研究活动。我们不仅考虑单相多铁质,而且考虑多铁质异质结构。我们解决关于磁电耦合的物理机制,以便突出这一不同学科的主干。一系列关于晶格对称、磁有序、铁电的产生、电介子激发、多铁畴结构和畴壁动力学以及多铁异质结构中的界面耦合的问题,将在一个更新的物理框架中重新审视。此外,一些紧急现象和相关的物理,包括磁天空和一般拓扑结构与磁电将被讨论。审查以一系列前瞻性和前瞻性的结论结束,这些结论可能不可避免地反映了作者的偏见,但肯定是关键的。
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来源期刊
Advances in Physics
Advances in Physics 物理-物理:凝聚态物理
CiteScore
67.60
自引率
0.00%
发文量
1
期刊介绍: Advances in Physics publishes authoritative critical reviews by experts on topics of interest and importance to condensed matter physicists. It is intended for motivated readers with a basic knowledge of the journal’s field and aims to draw out the salient points of a reviewed subject from the perspective of the author. The journal''s scope includes condensed matter physics and statistical mechanics: broadly defined to include the overlap with quantum information, cold atoms, soft matter physics and biophysics. Readership: Physicists, materials scientists and physical chemists in universities, industry and research institutes.
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