Interlayer Magnetic Interaction in the CrI3/CrSe2 Heterostructure

Qiu Hao Wang; Mei Yan Ni; Shu Jing Li; Fa Wei Zheng; Hong Yan Lu; Ping Zhang

doi:10.1088/0256-307X/41/5/057401

Interlayer Magnetic Interaction in the CrI₃/CrSe₂ Heterostructure

Qiu Hao Wang, Mei Yan Ni, Shu Jing Li, Fa Wei Zheng, Hong Yan Lu^*, Ping Zhang^*

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Based on first-principles calculations, we systematically study the stacking energy and interlayer magnetic interaction of the heterobilayer composed of CrI₃ and CrSe₂ monolayers. It is found that the stacking order plays a crucial role in the interlayer magnetic coupling. Among all possible stacking structures, the AA-stacking is the most stable heterostructure, exhibiting interlayer antiferromagnetic interactions. Interestingly, the interlayer magnetic interaction can be effectively tuned by biaxial strain. A 4.3% compressive strain would result in a ferromagnetic interlayer interaction in all stacking orders. These results reveal the magnetic properties of CrI₃/CrSe₂ heterostructure, which is expected to be applied to spintronic devices.

Original language	English
Article number	057401
Journal	Chinese Physics Letters
Volume	41
Issue number	5
DOIs	https://doi.org/10.1088/0256-307X/41/5/057401
Publication status	Published - 1 May 2024

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title = "Interlayer Magnetic Interaction in the CrI3/CrSe2 Heterostructure",

abstract = "Based on first-principles calculations, we systematically study the stacking energy and interlayer magnetic interaction of the heterobilayer composed of CrI3 and CrSe2 monolayers. It is found that the stacking order plays a crucial role in the interlayer magnetic coupling. Among all possible stacking structures, the AA-stacking is the most stable heterostructure, exhibiting interlayer antiferromagnetic interactions. Interestingly, the interlayer magnetic interaction can be effectively tuned by biaxial strain. A 4.3\% compressive strain would result in a ferromagnetic interlayer interaction in all stacking orders. These results reveal the magnetic properties of CrI3/CrSe2 heterostructure, which is expected to be applied to spintronic devices.",

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T1 - Interlayer Magnetic Interaction in the CrI3/CrSe2 Heterostructure

AU - Wang, Qiu Hao

AU - Ni, Mei Yan

AU - Li, Shu Jing

AU - Zheng, Fa Wei

AU - Lu, Hong Yan

AU - Zhang, Ping

PY - 2024/5/1

Y1 - 2024/5/1

N2 - Based on first-principles calculations, we systematically study the stacking energy and interlayer magnetic interaction of the heterobilayer composed of CrI3 and CrSe2 monolayers. It is found that the stacking order plays a crucial role in the interlayer magnetic coupling. Among all possible stacking structures, the AA-stacking is the most stable heterostructure, exhibiting interlayer antiferromagnetic interactions. Interestingly, the interlayer magnetic interaction can be effectively tuned by biaxial strain. A 4.3% compressive strain would result in a ferromagnetic interlayer interaction in all stacking orders. These results reveal the magnetic properties of CrI3/CrSe2 heterostructure, which is expected to be applied to spintronic devices.

AB - Based on first-principles calculations, we systematically study the stacking energy and interlayer magnetic interaction of the heterobilayer composed of CrI3 and CrSe2 monolayers. It is found that the stacking order plays a crucial role in the interlayer magnetic coupling. Among all possible stacking structures, the AA-stacking is the most stable heterostructure, exhibiting interlayer antiferromagnetic interactions. Interestingly, the interlayer magnetic interaction can be effectively tuned by biaxial strain. A 4.3% compressive strain would result in a ferromagnetic interlayer interaction in all stacking orders. These results reveal the magnetic properties of CrI3/CrSe2 heterostructure, which is expected to be applied to spintronic devices.

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SN - 0256-307X

VL - 41

JO - Chinese Physics Letters

JF - Chinese Physics Letters

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ER -

Interlayer Magnetic Interaction in the CrI₃/CrSe₂ Heterostructure

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