Prediction of Intrinsic Ferromagnetic Ferroelectricity in a Transition-Metal Halide Monolayer

Huang, Chengxi; Du, Yongping; Wu, Haiping; Xiang, Hongjun; Deng, Kaiming; Kan, Erjun

doi:10.1103/physrevlett.120.147601

Cited by 237 publications

(163 citation statements)

References 54 publications

(46 reference statements)

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“…The experience and knowledge learned from three-dimensional magnetoelectric crystals, as reviewed before, can be helpful to search/design low-dimensional multiferroics. For example, the generation of ferroelectricity by noncollinear spin texture has been predicted in Mxene monolayer [114] and the charge-orbital ordering concept has also been implemented in transition-metal halide monolayer to pursuit the ferromagnetic ferroelectricity [115]. Furthermore, the concept of a two-dimensional hyper-ferroelectric metal was proposed [116].…”

Section: Perspectivesmentioning

confidence: 99%

Magnetoelectricity in multiferroics: a theoretical perspective

Dong

Xiang

Dagotto

2019

National Science Review

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149

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The key physical property of multiferroic materials is the existence of a coupling between magnetism and polarization, i.e. magnetoelectricity. The origin and manifestations of magnetoelectricity can be very different in the available plethora of multiferroic systems, with multiple possible mechanisms hidden behind the phenomena. In this Review, we describe the fundamental physics that causes magnetoelectricity from a theoretical viewpoint.The present review will focus on the main stream physical mechanisms in both single phase multiferroics and magnetoelectric heterostructures. The most recent tendencies addressing possible new magnetoelectric mechanisms will also be briefly outlined.Magnetism and electricity are two fundamental physical phenomena which have been widely covered in elementary textbooks of electromagnetism and have led to a broad technological revolution within human civilization. Even today, these two crucial subjects remain at the frontier of active research, and are still attracting considerable attention within the scientific community for their indispensable scientific value and possible applications. In solids, magnetism and electricity originate from the spin and the charge degrees of freedom, respectively. The crossover between these two fascinating topics has much grown in recent years and it has developed into an emergent branch of Condensed Matter Physics calledGenerally speaking, magnetoelectric effects can exist in many systems, even in some that are nonmagnetic. In fact, the first example of a magnetoelectric effect was observed by Röntgen in 1888 in a dielectric material, which was magnetized when moving through an electric field [10]. Much more recently, the surface state of topological insulators was predicted to manifest magnetoelectric effects [11]. However, to develop magnetoelectricity of a large magnitude, and as a consequence of more considerable practical value, multiferroics seem to be the best playground. In multiferroics, both magnetic moments and electric dipole moments can be ordered, inducing robust macroscopic quantities such as magnetization and polarization. Moreover, crucially for applications, both moments are coupled. Then, these macroscopic quantities may be mutually controlled, for example modifying the magnetization by an electric voltage or modifying the polarization by a magnetic field, which is particularly useful to design new devices, such as for storage and sensors.However, conceptually the mere existence of multiferroics is highly non trivial [12]. For most magnetic materials, the magnetic moments arise from unpaired electrons in partially occupied d orbitals and/or f orbitals. However, the spontaneous formation of a charge dipole usually needs empty d orbitals as a condition of having a coordinate bond, i.e. the so-called d 0 rule. Thus, the key ions involved in typical magnetic materials and those in polar materials are different, making these two areas of research nearly isolated from each other. However, in 2003 the discovery of a large polarizatio...

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Section: Perspectivesmentioning

confidence: 99%

Magnetoelectricity in multiferroics: a theoretical perspective

Dong

Xiang

Dagotto

2019

National Science Review

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149

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“…The asymmetric Jahn–Teller distortion of octahedral CrBr 6 units induces in‐plane ferroelectricity coexisting with ferromagnetism in CrBr 3 0.5− . (Reprinted with permission from Reference . Copyright 2018 American Physical Society)…”

Section: Exploration Of Low‐dimensional Multiferroic Materialsmentioning

confidence: 99%

Progress and prospects in low‐dimensional multiferroic materials

Kan

2019

WIREs Comput Mol Sci

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Functional materials with ferroelectricity or multiferroicity based on two‐dimensional (2D) materials have been a fast developing field which attracts intensive investigations due to their potential applications and underlying new science. In this study, we review recent progress in theoretical simulation and experimental observation of low‐dimensional multiferroic materials, including exploring 2D van der Waals ferroelectrics, designing ferroelectrics or multiferroics by various manipulations such as chemical functionalization or external strain. The reported new physical mechanisms are also provided to explain the low‐dimensional multiferroics. We also discuss several exciting possibilities for design of devices based on these materials in novel applications. This article is categorized under: Structure and Mechanism > Computational Materials Science

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“…First-principles structural and magnetic energy calculations provide a quantitative explanation in terms of dramatically pressure-enhanced interactions between CuBr 2 chains. These large, pressure-tuned magnetic interactions motivate structural control in cuprous halides as a route to applied high-temperature multiferroicity.The search for application-suitable multiferroics [1-3] has advanced significantly over the last decade in both type-I and type-II materials [4][5][6][7][8][9]. Type-I multiferroics [10] have independent magnetic and ferroelectric transitions [11,12], meaning that even when both transition temperatures are high, the magnetoelectric coupling, and hence the scope for mutual control, is usually weak.…”

mentioning

confidence: 99%

“…The search for application-suitable multiferroics [1][2][3] has advanced significantly over the last decade in both type-I and type-II materials [4][5][6][7][8][9]. Type-I multiferroics [10] have independent magnetic and ferroelectric transitions [11,12], meaning that even when both transition temperatures are high, the magnetoelectric coupling, and hence the scope for mutual control, is usually weak.…”

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confidence: 99%

Giant pressure-enhancement of multiferroicity in CuBr2

Zhang

Xie

Liu

et al. 2020

Phys. Rev. Research

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Type-II multiferroic materials, in which ferroelectric polarization is induced by inversion non-symmetric magnetic order, promise new and highly efficient multifunctional applications based on mutual control of magnetic and electric properties. However, to date this phenomenon is limited to low temperatures. Here we report giant pressure-dependence of the multiferroic critical temperature in CuBr 2 : at 4.5 GPa it is enhanced from 73.5 to 162 K, to our knowledge the highest T C ever reported for non-oxide type-II multiferroics. This growth shows no sign of saturating and the dielectric loss remains small under these high pressures. We establish the structure under pressure and demonstrate a 60% increase in the two-magnon Raman energy scale up to 3.6 GPa. First-principles structural and magnetic energy calculations provide a quantitative explanation in terms of dramatically pressure-enhanced interactions between CuBr 2 chains. These large, pressure-tuned magnetic interactions motivate structural control in cuprous halides as a route to applied high-temperature multiferroicity.The search for application-suitable multiferroics [1-3] has advanced significantly over the last decade in both type-I and type-II materials [4][5][6][7][8][9]. Type-I multiferroics [10] have independent magnetic and ferroelectric transitions [11,12], meaning that even when both transition temperatures are high, the magnetoelectric coupling, and hence the scope for mutual control, is usually weak. The physics of most type-II multiferroics [10,[13][14][15] involves frustrating magnetic interactions that give rise to a spiral magnetic order [16], which immediately generates a ferroelectric polarization by the inverse Dzyaloshinskii-Moriya mechanism [17][18][19][20][21]. However, an intrinsic drawback of magnetic frustration is that it suppresses the onset of long-range order, and hence most currently available type-II multiferroics operate only at low tempera-tures [14].A generic route to higher operating temperatures in type-II multiferroics is to increase the strength of the magnetic interactions. This can, in principle, be achieved through structural alterations, for which perhaps the cleanest method is an applied pressure [22][23][24][25][26]. Pressure, broadly construed to include chemical pressure and substrate pressure, acts to increase electronic hybridization without introducing disorder. In the most minimal model for a magnetic insulator, the antiferromagnetic (AF) exchange interaction is given by J = 4t 2 /U , where t is the orbital hybridization and U the on-site Coulomb repulsion. However, excessive t risks driving the system metallic, thus losing its magnetic and ferroelectric properties. The most scope for achieving large J values is offered by large initial values of both t and U , making the spin-1/2 Cu 2+ ion particularly promising in view of its often strong on-site correlations and significant orbital hybridization with ligands. It is not a coincidence that complex copper oxides become high-temperature superconductors after ...

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Prediction of Intrinsic Ferromagnetic Ferroelectricity in a Transition-Metal Halide Monolayer

Cited by 237 publications

References 54 publications

Magnetoelectricity in multiferroics: a theoretical perspective

Magnetoelectricity in multiferroics: a theoretical perspective

Progress and prospects in low‐dimensional multiferroic materials

Giant pressure-enhancement of multiferroicity in CuBr2

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