# Wallpaper Fermions and the Nonsymmorphic Dirac Insulator

**Authors:** Benjamin J. Wieder, Barry Bradlyn, Zhijun Wang, Jennifer Cano,, Youngkuk Kim, Hyeong-Seok D. Kim, A. M. Rappe, C. L. Kane, and B. Andrei, Bernevig

arXiv: 1705.01617 · 2018-07-24

## TL;DR

This paper introduces a new class of topological insulators called nonsymmorphic Dirac insulators, characterized by unique surface states protected by wallpaper group symmetries, and predicts their realization in specific materials.

## Contribution

It identifies new topological crystalline phases protected by wallpaper group symmetries and predicts their realization in materials like Sr₂Pb₃ and Au₂Y₃.

## Key findings

- Discovery of a new topological phase with a single Dirac fermion surface state.
- Prediction of materials hosting nonsymmorphic Dirac fermions.
- Development of topological invariants for orthorhombic space groups.

## Abstract

Recent developments in the relationship between bulk topology and surface crystal symmetry have led to the discovery of materials whose gapless surface states are protected by crystal symmetries. In fact, there exists only a very limited set of possible surface crystal symmetries, captured by the 17 "wallpaper groups." We show that a consideration of symmetry-allowed band degeneracies in the wallpaper groups can be used to understand previous topological crystalline insulators, as well as to predict new examples. In particular, the two wallpaper groups with multiple glide lines, $pgg$ and $p4g$, allow for a new topological insulating phase, whose surface spectrum consists of only a single, fourfold-degenerate, true Dirac fermion. Like the surface state of a conventional topological insulator, the surface Dirac fermion in this "nonsymmorphic Dirac insulator" provides a theoretical exception to a fermion doubling theorem. Unlike the surface state of a conventional topological insulator, it can be gapped into topologically distinct surface regions while keeping time-reversal symmetry, allowing for networks of topological surface quantum spin Hall domain walls. We report the theoretical discovery of new topological crystalline phases in the A$_2$B$_3$ family of materials in SG 127, finding that Sr$_2$Pb$_3$ hosts this new topological surface Dirac fermion. Furthermore, (100)-strained Au$_2$Y$_3$ and Hg$_2$Sr$_3$ host related topological surface hourglass fermions. We also report the presence of this new topological hourglass phase in Ba$_5$In$_2$Sb$_6$ in SG 55. For orthorhombic space groups with two glides, we catalog all possible bulk topological phases by a consideration of the allowed non-abelian Wilson loop connectivities, and we develop topological invariants for these systems. Finally, we show how in a particular limit, these crystalline phases reduce to copies of the SSH model.

## Full text

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## Figures

21 figures with captions in the complete paper: https://tomesphere.com/paper/1705.01617/full.md

## References

106 references — full list in the complete paper: https://tomesphere.com/paper/1705.01617/full.md

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Source: https://tomesphere.com/paper/1705.01617