Quantum spin Hall effect in bilayer honeycomb lattices with C-type antiferromagnetic order

Abstract

We propose a scheme to realize time-reversal symmetry-broken quantum spin Hall insulators using bilayer honeycomb lattices, combining intrinsic spin-orbit coupling, C-type antiferromagnetic ordering, and staggered potentials. The C-type antiferromagnetic order emerges from the interplay between intralayer antiferromagnetism and interlayer ferromagnetism. The system's topological properties are characterized by the spin Chern number. We present the topological phase diagram of the bilayer honeycomb lattice, providing a detailed insight into the stability and tunability of the quantum spin Hall effect in this system. The presence of helical edge states is confirmed by the measurement of quantized longitudinal resistance values of 3/2(h/e2) and 1/2(h/e2) in a sixterminal Hall-bar device. Remarkably, this quantum spin Hall insulator phase is protected by interlayer parity-time (PT) symmetry, despite the breaking of time-reversal symmetry.

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