Layer-polarized anomalous Hall effect in the MnBi2Te4/In2Se3 (In2Te3) heterostructures

Layer-polarized anomalous Hall effect in the MnBi2Te4/In2Se3 (In2Te3) heterostructures

The layer-polarized anomalous Hall effect has emerged as a novel phenomenon in the field of condensed matter physics, holding significant promise for future applications in designing low-dissipation devices. Currently, the layer-polarized anomalous Hall effect has been theoretically predicted or exp...

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Bibliographic Details
Main Authors: Hong Xu, Xuqi Li, Haidan Sang, Yu Zhang, Wenying Mu, Shifei Qi
Format: Article
Language:English
Published: Elsevier 2024-09-01
Series:Materials Today Quantum
Subjects:
Anomalous Hall effect
Topological insulator
Ferroelectric polarization
Hall conductivity
Online Access:http://www.sciencedirect.com/science/article/pii/S295025782400012X
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Summary:The layer-polarized anomalous Hall effect has emerged as a novel phenomenon in the field of condensed matter physics, holding significant promise for future applications in designing low-dissipation devices. Currently, the layer-polarized anomalous Hall effect has been theoretically predicted or experimentally demonstrated through the application of external electric fields or the utilization of sliding ferroelectricity in diverse systems. Here, through first-principles calculations, we propose a pathway to realize the layer-polarized anomalous Hall effect by constructing A-type antiferromagnetic topological insulator MnBi2Te4 based heterostructures with ferroelectric materials In2Se3/In2Te3. Our results firstly show that the sizeable band splitting (larger than 20 meV) appears in the antiferromagnetic 4 septuple layers MnBi2Te4/In2Se3 system due to broken inversion symmetry. Further calculations approve that the layer-polarized anomalous Hall conductivity with reversal signs can be observed in the antiferromagnetic 4 septuple layers MnBi2Te4/In2Se3 (In2Te3) systems by shifting the Fermi energy level. Additionally, it is also found that ferrimagnetic 4 septuple layers MnBi2Te4/In2Se3 (In2Te3) can be realized by controlling the direction of ferroelectric polarization of ferroelectric materials. Thus, the resulting layer-polarized anomalous Hall effect may be switchable in our suggested systems. This work provides feasible systems for the further experimental realization of the layer-polarized anomalous Hall effect.
ISSN:2950-2578

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