Litcius/Paper detail

Realization of a three-dimensional photonic higher-order topological insulator

Ziyao Wang, Yan Meng, Bei Yan, Dong Zhao, Linyun Yang, Jingming Chen, Minqi Cheng, Xiao Tao, Perry Ping Shum, Gui-Geng Liu, Yihao Yang, Hongsheng Chen, Xiang Xi, Zhenxiao Zhu, Biye Xie, Zhen Gao

2025Nature Communications19 citationsDOIOpen Access PDF

Abstract

The discovery of photonic higher-order topological insulators (HOTIs) has expanded our understanding of band topology, offering robust lower-dimensional boundary states for photonic devices. However, realizing three-dimensional (3D) photonic HOTIs remains challenging due to the vectorial and leaky nature of electromagnetic waves. Here, we present the experimental realization of a 3D Wannier-type photonic HOTI using a tight-binding-like metal-cage photonic crystal, whose band structures align with a 3D tight-binding model via confined Mie resonances. Microwave near-field measurements reveal coexisting topological surface, hinge, and corner states in a single 3D photonic HOTI, consistent with theoretical predictions. Remarkably, these states are robust and self-guided even within the light cone continuum, functioning without ancillary cladding. This work paves the way for multi-dimensional manipulation of electromagnetic waves on 3D cladding-free photonic bandgap materials, enabling practical applications in 3D topological integrated photonic devices. Here, the authors report the experimental realization of a 3D Wannier-type photonic HOTI, which hosts coexisting self-guided topological surface, hinge, and corner states in a single 3D tight binding-like photonic crystal.

Topics & Concepts

Realization (probability)Topological insulatorPhotonicsTopology (electrical circuits)Order (exchange)PhysicsComputer scienceOptoelectronicsMathematicsQuantum mechanicsCombinatoricsBusinessFinanceStatisticsTopological Materials and PhenomenaPhotonic Crystals and ApplicationsPhotonic and Optical Devices