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Paper detail

Charge Carrier Mediation and Ferromagnetism induced in MnBi6Te10 Magnetic Topological Insulators by antimony doping

A new kind of intrinsic magnetic topological insulators (MTI) MnBi2Te4 family have shed light on the observation of novel topological quantum effect such as quantum anomalous Hall effect (QAHE). However, the strong anti-ferromagnetic (AFM) coupling and high carrier concentration in the bulk hinder the practical applications. In closely related materials MnBi4Te7 and MnBi6Te10, the interlayer magnetic coupling is greatly suppressed by Bi2Te3 layer intercalation. However, AFM is still the ground state in these compounds. Here by magnetic and transport measurements, we demonstrate that Sb substitutional dopant plays a dual role in MnBi6Te10, which can not only adjust the charge carrier type and the concentration, but also induce the solid into a ferromagnetic (FM) ground state. AFM ground state region which is also close to the charge neutral point can be found in the phase diagram of Mn(SbxBi1-x)6Te10 when x ~ 0.25. An intrinsic FM-MTI candidate is thus demonstrated, and it may take a step further for the realization of high-quality and high-temperature QAHE and the related topological quantum effects in the future.

preprint2022arXivOpen access
Hangkai XieFucong FeiFenzhen FangBo ChenJingwen GuoYu DuWuyi QiYufan PeiTianqi WangMuhammad NaveedShuai ZhangMinhao ZhangXuefeng WangFengqi Song
cond-mat.mtrl-sci
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Hangkai XieFucong FeiFenzhen FangBo ChenJingwen GuoYu DuWuyi QiYufan PeiTianqi WangMuhammad NaveedShuai ZhangMinhao ZhangXuefeng WangFengqi Song

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