Higher Chern numbers in multilayer ($\mathcal{N} \ge 2$) Lieb lattices: Topological transitions and quadratic band crossing lines

TL;DR

This paper explores multilayer Lieb lattices with spin-orbit coupling, revealing topological transitions and higher Chern numbers due to emergent non-symmorphic symmetry and quadratic band crossing lines.

Contribution

It uncovers how stacking multilayer Lieb lattices induces non-symmorphic symmetry and higher Chern numbers, a novel topological phenomenon not previously studied.

Findings

Multilayer Lieb lattices exhibit higher Chern numbers $ $ due to stacking.

Emergent non-symmorphic symmetry causes quadratic band crossing lines.

Topological properties analyzed using non-abelian Berry phases.

Abstract

We consider a hitherto unexplored setting of stacked multilayer ($\mathcal{N}$) Lieb lattice which undergoes an unusual topological transition in the presence of intra-layer spin-orbit coupling (SOC). The specific stacking configuration induces an effective non-symmorphic 2D lattice structure, even though the constituent monolayer Lieb lattice is characterized by a symmorphic space group. This emergent non-symmorphicity leads to multiple doubly-degenerate bands extending over the edge of the Brillouin zone (i.e. Quadratic Band Crossing Lines). In the presence of intra-layer SOC, these doubly-degenerate bands typically form three $\mathcal{N}$-band subspaces, mutually separated by two band gaps. We analyze the topological properties of these multi-band subspaces, using specially devised Wilson loop operators to compute non-abelian Berry phases, in order to show that they carry a higher Chern number $\mathcal{N}$.