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Two-dimensional higher-order topological metals

Lizhou Liu, Cheng-Ming Miao, Qing‐Feng Sun, Ying‐Tao Zhang

2024Physical review. B./Physical review. B10 citationsDOIOpen Access PDF

Abstract

We investigate the energy band structure and energy levels of graphene with staggered intrinsic spin-orbit coupling and in-plane Zeeman fields. Our study demonstrates that staggered intrinsic spin-orbit coupling induces bulk band crossover at the $K$ and ${K}^{\ensuremath{'}}$ valleys and generates antihelical edge states at the zigzag boundaries, resulting in topological metallic phases. Quantized transport coefficients confirm the existence of these antihelical edge states. Furthermore, an in-plane Zeeman field, regardless of orientation, opens a gap in the antihelical edge states while preserving bulk band closure, leading to higher-order topological metals with corner states. We also validate the presence of these corner states in nanoflakes with zigzag boundaries and confirm the metallic phases with crossed bands through a continuum low-energy model analysis.

Topics & Concepts

Order (exchange)Topology (electrical circuits)MathematicsCombinatoricsBusinessFinanceTopological Materials and PhenomenaGraphene research and applications2D Materials and Applications
Two-dimensional higher-order topological metals | Litcius