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. 2020 Jun 19;2020:1768918. doi: 10.34133/2020/1768918

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Copyright © 2020 Vertikasari P. Ningrum et al.

Exclusive Licensee Science and Technology Review Publishing House. Distributed under a Creative Commons Attribution License (CC BY 4.0).

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(a) Scheme of three basic mechanisms of anomalous Hall effect. (b) Hall resistivity of Cr_0.68Se at 2 K. (c, d) Hall resistivity of Fe₃GeTe₂ of 12 nm thick under various temperatures (c) and of varying thicknesses at 2 K (d) with H//c. (e, f) Hall resistivity of Co₃Sn₂S₂ as a function of out-of-plane magnetic field at 100, 50, and 2 K (e) and as a function of temperature at zero magnetic field (f). (g) Scheme of the crystal lattice and magnetic structure of MnBi_2nTe_3n+1 family (n = 0, 1, 2, 3, ⋯). (h) Illustration of intrinsic axion insulator in even layers and quantum anomalous Hall (QAH) insulator in odd layers. (i) Topological phases and magnetic phases of 2D and 3D MnBi₂Te₄. (j) Topological phase diagram in the 2D limit of a 3D topological insulator as a function of the crystal thickness L and magnetization gM, including the normal insulator (grey area), quantum spin Hall effect (QSHE) with preserved time-reversal symmetry (blue line), QSHE with broken time-reversal symmetry (yellow area), and quantum anomalous Hall effect (QAHE) (cyan area). (k) Magnetic transition in five-layer MnBi₂Te₄ under H//c and H//ab at 1.6 K. (l) Hall resistivity of bulk MnBi₄Te₇ at 2 K with H//c and I//ab. (m, n) Magnetization, Hall resistivity, and planar magnetoresistivity of few-layer MnBi₆Te₁₀ with H//c of ±0.3 T (m) and MnBi₈Te₁₃ with H//c of ±0.2 T (n) at 2 K. Panels (a, b) are reproduced with permission from ref. [43], copyright 2017 Applied Physics Letters. Panel (c) is reproduced with permission from ref. [46], copyright 2018 Nature Materials. Panel (d) is reproduced with permission from ref. [47], copyright 2018 Nature Communications. Panels (e, f) are reproduced with permission from ref. [48], copyright 2018 Nature Physics. Panels (g, n) are reproduced with permission from ref. [59], copyright 2019 Arxiv. Panels (h, i) are reproduced with permission from ref. [54], copyright 2019 Science Advances. Panel (j) is reproduced with permission from ref. [57], copyright 2019 Physical Review Letters. Panel (k) is reproduced with permission from ref. [55], copyright 2019 Arxiv. Panel (l) is reproduced with permission from ref. [56], copyright 2020 Nature Communications. Panel (m) is reproduced with permission from ref. [58], copyright 2019 Arxiv.