npj Computational Materials (Apr 2021)

Discovery of higher-order topological insulators using the spin Hall conductivity as a topology signature

  • Marcio Costa,
  • Gabriel R. Schleder,
  • Carlos Mera Acosta,
  • Antonio C. M. Padilha,
  • Frank Cerasoli,
  • Marco Buongiorno Nardelli,
  • Adalberto Fazzio

DOI
https://doi.org/10.1038/s41524-021-00518-4
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 6

Abstract

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Abstract The discovery and realization of topological insulators, a phase of matter which hosts metallic boundary states when the d-dimension insulating bulk is confined to (d − 1)-dimensions, led to several potential applications. Recently, it was shown that protected topological states can manifest in (d − 2)-dimensions, such as hinge and corner states for three- and two-dimensional systems, respectively. These nontrivial materials are named higher-order topological insulators (HOTIs). Here we show a connection between spin Hall effect and HOTIs using a combination of ab initio calculations and tight-binding modeling. The model demonstrates how a non-zero bulk midgap spin Hall conductivity (SHC) emerges within the HOTI phase. Following this, we performed high-throughput density functional theory calculations to find unknown HOTIs, using the SHC as a criterion. We calculated the SHC of 693 insulators resulting in seven stable two-dimensional HOTIs. Our work guides novel experimental and theoretical advances towards higher-order topological insulator realization and applications.