Stacking-dependent topological electronic structures in honeycomb-kagome heterolayersopen access
- Authors
- Bark, Chan Bin; Kim, Hanbyul; Pak, Seik; Min, Hong-Guk; Ahn, Sungkyun; Kim, Youngkuk; Park, Moon Jip
- Issue Date
- Jul-2025
- Publisher
- NATURE PUBLISHING GROUP
- Keywords
- Band Structure; Geometry; Heterojunctions; Honeycomb Structures; Topology; Band Inversion; Biaxial Phasis; Electronic.structure; Heterolayers; Kagome Lattice; Novel Materials; Property; Stackings; Synthesised; Two-dimensional Lattices; Lattice Mismatch
- Citation
- npj 2D Materials and Applications, v.9, no.1, pp 1 - 8
- Pages
- 8
- Indexed
- SCIE
SCOPUS
- Journal Title
- npj 2D Materials and Applications
- Volume
- 9
- Number
- 1
- Start Page
- 1
- End Page
- 8
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/208314
- DOI
- 10.1038/s41699-025-00582-0
- ISSN
- 2397-7132
2397-7132
- Abstract
- Heterostructures of stacked two-dimensional lattices have shown great promise for engineering novel material properties. As an archetypal example of such a system, the hexagon-shared honeycomb-kagome lattice has been experimentally synthesized in various material platforms. In this work, we explore three rotationally symmetric variants of the honeycomb-kagome lattice: the hexagonal, triagonal, and biaxial phases. While the triagonal and biaxial phases exhibit trivial insulating and Dirac semimetal band structures, respectively, the hexagonal phase hosts a higher-order topological phase driven by band inversion near the Gamma-point. This highlights a key distinction from the conventional band inversions at the K-point observed in hexagonal homobilayer systems. Furthermore, we demonstrate how the distinct topological properties of these phases result in network band structures within moir & eacute; heterostructures formed by twisted or lattice-mismatched HK systems. These network band structures can be experimentally observed through extrinsic twisting or intrinsic lattice mismatch between the honeycomb and kagome systems.
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