Intertwined Dirac cones induced by anisotropic coupling in antiferromagnetic topological insulator

Antiferromagnetic topological insulators (AFM TIs), which host magnetically gapped Dirac-cone surface states and exhibit many exotic physical phenomena, have attracted great attention. The coupling between the top and bottom surface states becomes significant and plays a crucial role in its low-energy physics, as the thickness of an AFM TI film decreases. Here, we find that the coupled surface states can be intertwined to give birth to a set of $2n$ brand new Dirac cones, dubbed \emph{intertwined Dirac cones}, through the anisotropic coupling due to the $n$-fold crystalline rotation symmetry $C_{nz}$ ($n=2, 3, 4, 6$) in the presence of an out-of-plane electric field. Interestingly, we also find that the warping effect further drives the intertwined Dirac-cone state into a quantum anomalous Hall phase with a high Chern number ($C=n$). Then, we demonstrate the emergent six intertwined Dirac cones and the corresponding Chern insulating phase with a high Chern number ($C=3$) in MnBi$_2$Te$_4$$/$(Bi$_2$Te$_3$)$_{\mathrm{m}}/$MnBi$_2$Te$_4$ heterostructures through first-principles calculations. This work discovers a new intertwined Dirac-cone state in AFM TI thin films and also reveals a new mechanism for designing the quantum anomalous Hall state with a high Chern number.