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Main Authors: Shi, Zhijian, Xu, Shengjie, Wang, Jianfeng, Du, Yi, Hao, Weichang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.22348
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author Shi, Zhijian
Xu, Shengjie
Wang, Jianfeng
Du, Yi
Hao, Weichang
author_facet Shi, Zhijian
Xu, Shengjie
Wang, Jianfeng
Du, Yi
Hao, Weichang
contents As an ideal platform for studying interplays between symmetry, topology and magnetism, the magnetic topological insulator (MTI) MnBi2Te4 has attracted extensive attentions. However, its strong n-type intrinsic defects hinder the realizations of exotic phenomena. Stimulated by recent discoveries that Ge doping can efficiently tune the position of Fermi level, here we systematically investigate the band evolution and topological phase diagram with doping concentration from MTI MnBi2Te4 to strong topological insulator GeBi2Te4. Different from magnetically doped Bi2Se3, the topology here is determined by competition of two band inversions arising from band folding of two time-reversal invariant momenta between antiferromagnetic and nonmagnetic/ferromagnetic unit cells. By employing a band momentum mapping method, besides the known MTI phase, remarkably, we find two classes of magnetic Dirac semimetal phases at antiferromagnetic state, two classes of Weyl semimetal phases at ferromagnetic state, and an intermediate trivial state at different doping regions. Interestingly, the trivial state can be tuned into a Weyl phase with two coexisting band inversions and extraordinarily long Fermi arcs by a small strain. Our work reveals diverse topological states with intrinsic quantum phenomena can be achieved with great potential for designing future electronic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2505_22348
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Emergence of Diverse Topological States in Ge Doped MnBi2Te4
Shi, Zhijian
Xu, Shengjie
Wang, Jianfeng
Du, Yi
Hao, Weichang
Materials Science
Other Condensed Matter
Computational Physics
Quantum Physics
As an ideal platform for studying interplays between symmetry, topology and magnetism, the magnetic topological insulator (MTI) MnBi2Te4 has attracted extensive attentions. However, its strong n-type intrinsic defects hinder the realizations of exotic phenomena. Stimulated by recent discoveries that Ge doping can efficiently tune the position of Fermi level, here we systematically investigate the band evolution and topological phase diagram with doping concentration from MTI MnBi2Te4 to strong topological insulator GeBi2Te4. Different from magnetically doped Bi2Se3, the topology here is determined by competition of two band inversions arising from band folding of two time-reversal invariant momenta between antiferromagnetic and nonmagnetic/ferromagnetic unit cells. By employing a band momentum mapping method, besides the known MTI phase, remarkably, we find two classes of magnetic Dirac semimetal phases at antiferromagnetic state, two classes of Weyl semimetal phases at ferromagnetic state, and an intermediate trivial state at different doping regions. Interestingly, the trivial state can be tuned into a Weyl phase with two coexisting band inversions and extraordinarily long Fermi arcs by a small strain. Our work reveals diverse topological states with intrinsic quantum phenomena can be achieved with great potential for designing future electronic devices.
title Emergence of Diverse Topological States in Ge Doped MnBi2Te4
topic Materials Science
Other Condensed Matter
Computational Physics
Quantum Physics
url https://arxiv.org/abs/2505.22348