Structure-driven intercalated architecture of septuple-atomic-layer MA2Z4 family with diverse properties from semiconductor to topological insulator to Ising superconductor

Abstract

Motivated by the fact that septuple-atomic-layer MnBi2Te4 can be structurally viewed as the combination of double-atomic-layer MnTe intercalating into quintuple-atomic-layer Bi2Te3, we present a general approach of constructing twelve septuple-atomic-layer αi- and βi-MA2Z4 monolayer family (i = 1 to 6) by intercalating MoS2-type MZ2 monolayer into InSe-type A2Z2 monolayer. Besides reproducing the experimentally synthesized α1-MoSi2N4, α1-WSi2N4 and β5-MnBi2Te4 monolayer materials, another 66 thermodynamically and dynamically stable MA2Z4 were predicted, which span a wide range of properties upon the number of valence electrons (VEC). MA2Z4 with the rules of 32 or 34 VEC are mostly semiconductors with direct or indirect band gap and, however, with 33 VEC are generally metal, half-metal ferromagnetism, or spin-gapless semiconductor upon whether or not an unpaired electron is spin polarized. Moreover, we propose α2-WSi2P4 for the spin-valley polarization, α1-TaSi2N4 for Ising superconductor and β2-SrGa2Se4 for topological insulator.