The recent discovered antiferromagnetic topological insulators in Mn-Bi-Te family with intrinsic magnetic ordering have rapidly drawn broad interest since its cleaved surface state is believed to be gapped, hosting the unprecedented axion states with half-integer quantum Hall effect. Here, however, we show unambiguously by using high-resolution angle-resolved photoemission spectroscopy that a gapless Dirac cone at the (0001) surface of MnBi2Te4 exists between the bulk band gap. Such unexpected surface state remains unchanged across the bulk Né el temperature, and is even robust against severe surface degradation, indicating additional topological protection. Through symmetry analysis and ab-initio calculations we consider different types of surface reconstruction of the magnetic moments as possible origins giving rise to such linear dispersion. Our results reveal that the intrinsic magnetic topological insulator hosts a rich platform to realize various topological phases such
The layered MnBi2nTe3n+1 family represents the first intrinsic antiferromagnetic topological insulator (AFM TI, protected by a combination symmetry S ) ever discovered, providing an ideal platform to explore novel physics such as quantum anomalous Hall effect at elevated temperature and axion electrodynamics. Recent angle-resolved photoemission spectroscopy (ARPES) experiments on this family have revealed that all terminations exhibit (nearly) gapless topological surface states (TSSs) within the AFM state, violating the definition of the AFM TI, as the surfaces being studied should be S -breaking and opening a gap. Here we explain this curious paradox using a surface-bulk band hybridization picture. Combining ARPES and first-principles calculations, we prove that only an apparent gap is opened by hybridization between TSSs and bulk bands. The observed (nearly) gapless features are consistently reproduced by tight-binding simulations where TSSs are coupled to a Rashba-split bulk band. The Dirac-cone-like spectral features are actually of bulk origin, thus not sensitive to the S -breaking at the AFM surfaces. This picture explains the (nearly) gapless behaviour found in both Bi2Te3-and MnBi2Te4-terminated surfaces and is applicable to all terminations of MnBi2nTe3n+1 family. Our findings highlight the role of band hybridization, superior to magnetism in this case, in shaping the general surface band structure in magnetic topological materials for the first time.
The magnetic structures of the intrinsic magnetic topological insulator family MnBi2Te4(Bi2Te3)n (n = 0, 1, 2) adopt A-type antiferromagnetic (AFM) configurations with ferromagnetic (FM) MnBi2Te4 layers stacking through van der Waals interactions. While the interlayer coupling could be effectively tunned by the number of Bi2Te3 spacer layers n, the intralayer FM exchange coupling is considered too robust to control. Here, by applying hydrostatic pressure up to 3.5 GPa as an external knob, we discover the opposite responses of magnetic properties for MnBi2Te4(Bi2Te3)n with n = 1 and 2. In MnBi4Te7, the Né el temperature decreases with an increasing saturation field as pressure increases, indicating an enhanced interlayer AFM coupling. In sharp contrast, both the magnetic susceptibility and magneto-tranport measurements show that MnBi6Te10 experiences a phase transition from A-type AFM to quasi two-dimensional FM state with a suppressed saturation field under pressure. First-principles calculations reveal the essential role of the intralayer exchange coupling, which contains the competition between the AFM-preferred direct exchange and FM-preferred superexchange coupling, in determining these magnetic properties. Such a magnetic phase transition is also observed in Sb-doped MnBi6Te10 due to similar mechanism, where the in-plane lattice constant is effectively reduced.
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