Magnetic toroidicity

Xu, Xianghan; Huang, Fei-Ting; Cheong, Sang-Wook

doi:10.1088/1361-648x/ad2426

J. Phys.: Condens. Matter

2024

DOI: 10.1088/1361-648x/ad2426

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Magnetic toroidicity

Xianghan Xu,

Fei-Ting Huang,

Sang-Wook Cheong

Abstract: Directional non-reciprocity refers to the phenomenon where the motion in one direction differs from the motion in the opposite direction. This behavior is observed across various systems, such as one-way traffic and materials displaying electronic/optical directional dichroism, characterized by the symmetry of velocity vectors. Magnetic toroidal moments (MTMs), which typically arise from rotational spin arrangements, also possess the symmetry of velocity vectors, making them inherently directionally non-recipr… Show more

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Cited by 3 publications

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Kinetomagnetism of chirality and its applications

Cheong,

Huang

2024

Applied Physics Letters

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Chiral functionalities exhibited by systems lacking any mirror symmetry encompass natural optical activity, magnetochiral effect, diagonal current-induced magnetization, chirality-selective spin-polarized current of charged electrons or neutral neutrons, self-inductance, and chiral phonons. These phenomena are unified under the hypothesis of “kinetomagnetism of chirality,” which posits that any moving (charged or neutral) object in chiral systems induces magnetization in its direction of motion, consequently imparting chirality to the object due to this induced magnetization. We also found conjugate relationships among the kinetomagnetism of chirality, “linear magnetoelectricity,” and “electric field-induced directional nonreciprocity,” highlighting their interconnections with magnetic, electric, and toroidal orders. The concept of the kinetomagnetism of chirality will be an essential basis for the theoretical understanding of known chiral phenomena, such as natural optical activity or chiral phonons, and also the discovery of unexplored chiral functionalities.

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Kinetomagnetism of chirality and its applications

Cheong,

Huang

2024

Applied Physics Letters

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Spontaneous Magnetization Induced by Antiferromagnetic Toroidal Ordering

Hayami

2024

Nanomaterials

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The magnetic toroidal dipole moment, which is induced by a vortex-type spin texture, manifests itself in parity-breaking physical phenomena, such as a linear magnetoelectric effect and nonreciprocal transport. We elucidate that a staggered alignment of the magnetic toroidal dipole can give rise to spontaneous magnetization even under antiferromagnetic structures. We demonstrate the emergence of uniform magnetization by considering the collinear antiferromagnetic structure with the staggered magnetic toroidal dipole moment on a bilayer zigzag chain. Based on the model calculations, we show that the interplay between the collinear antiferromagnetic mean field and relativistic spin-orbit coupling plays an important role in inducing the magnetization.

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Symmetry Classification of Antiferromagnets with Four Types of Multipoles

Hayami

2024

Symmetry

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A plethora of antiferromagnetic structures have been so far found in condensed matter physics, where the antiferromagnetic phase transition is characterized by symmetry lowering under the magnetic point group. Depending on the types of symmetry lowering, various cross-correlation phenomena, such as the anomalous Hall effect, magneto-electric effect, and magneto-piezoelectric effect, emerge below the critical temperature. We revisit a close relationship between the symmetry of the antiferromagnetic structures and cross-correlations based on the augmented multipoles consisting of electric, magnetic, magnetic toroidal, and electric toroidal multipoles with different spatial inversion and time-reversal parities. The symmetry classification will be useful for further exploration of functional antiferromagnetic materials.

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Magnetic toroidicity

Cited by 3 publications

References 37 publications

Kinetomagnetism of chirality and its applications

Kinetomagnetism of chirality and its applications

Spontaneous Magnetization Induced by Antiferromagnetic Toroidal Ordering

Symmetry Classification of Antiferromagnets with Four Types of Multipoles

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