Abstract

By means of first-principles calculations and crystal structure searching techniques, we predict that a new NaCaBi family crystallized into the ZrBeSi-type structure (\ie $P6_{3}/mmc$) are strong topological insulators (STIs). Taking $P6_{3}/mmc$ NaCaBi as an example, the calculated band structure indicates that there is a band inversion between two opposite-parity bands at the $\Gamma$ point. In contrast to the well-known Bi$_2$Se$_3$ family, the band inversion in the NaCaBi family has already occured even without spin-orbit coupling (SOC), giving rise to a nodal ring surrounding $\Gamma$ in the $k_z=0$ plane (protected by $M_z$ symmetry). With time reversal symmetry $(\cal T)$ and inversion symmetry $(\cal I)$, the spinless nodal-line metallic phase protected by $[{\cal TI}]^2=1$ is the weak-SOC limit of the spinful topological insulating phase. Upon including SOC, the nodal ring is gapped, driving the system into a STI. Besides inversion symmetry, the nontrivial topology of NaCaBi can also be indicated by $\bar{6}$ symmetry. More surprisingly, the SOC-induced band gap in NaCaBi is about 0.34 eV, which is larger than the energy scale of room temperature. Four other compounds (KBaBi, KSrBi, RbBaBi and RbSrBi) in the family are stable at ambient pressure, both in thermodynamics and lattice dynamics, even though the gaps of them are smaller than that of NaCaBi. Thus, they provide good platforms to study topological states both in theory and experiments.

Highlights

  • Topological insulators (TIs) have been studied broadly and deeply in both theory and experiments since the twodimensional quantum spin Hall effect (2D TI) was proposed in 2005 [1]

  • From the phase diagrams based on convex hull analysis of formation enthalpies for the Na-Ca-Bi ternary system at 0 and 10 GPa, shown in Fig. 5, we find that stoichiometric NaCaBi crystallizes in the Pnma phase at 0 GPa and P63/mmc phase at 10 GPa, respectively

  • Our calculations reveal that the P63/mmc phase becomes preferred at pressures higher than 1 GPa

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Summary

INTRODUCTION

Topological insulators (TIs) have been studied broadly and deeply in both theory and experiments since the twodimensional quantum spin Hall effect (2D TI) was proposed in 2005 [1]. Though many TI candidates and corresponding interesting properties have been proposed [2,23,24,33,34], TIs with relatively large band gaps and clear 2D Dirac-cone surface states as the Bi2Se3 family are rare. Calculations of the band structures indicate that without spin-orbit coupling (SOC), P63/mmc NaCaBi is a topological semimetal with a nodal ring surrounding the point in the kz = 0 plane. Four other dynamically stable XYBi compounds with similar electronic structures and STI natures are proposed (See details in the Appendix)

The crystal structures of stoichiometric NaCaBi
Low-energy effective model
DISCUSSION

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