Twisted nodal wires and three-dimensional quantum spin Hall effect in distorted square-net compounds
Abstract
Recently, square-net materials have attracted lots of attention for the Dirac semimetal phase with negligible spin-orbit coupling (SOC) gap, e.g. ZrSiS/LaSbTe and CaMnSb2. In this paper, we demonstrate that the Jahn-Teller effect enlarges the nontrivial SOC gap in the distorted structure, e.g. LaAsS and SrZnSb2. Its distorted X square-net layer (X= P, As, Sb, Bi) resembles a quantum spin Hall (QSH) insulator. Since these QSH layers are simply stacked in the x direction and weakly coupled, three-dimensional QSH effect can be expected in these distorted materials, such as insulating compounds CeAs1+xSe1-y and EuCdSb2. Our detailed calculations show that it hosts two twisted nodal wires without SOC [each consists of two noncontractible time-reversal symmetry- and inversion symmetry-protected nodal lines touching at a fourfold degenerate point], while with SOC it becomes a topological crystalline insulator with symmetry indicators (000; 2) and mirror Chern numbers (0, 0). The nontrivial band topology is characterized by a generalized spin Chern number Cs+=2 when there is a gap between two sets of sx eigenvalues. The nontrivial topology of these materials can be well reproduced by our tight-binding model and the calculated spin Hall conductivity is quantized to σxyz = (e)Gxe2π h with Gx a reciprocal lattice vector.
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