Abstract
Higher-order topological insulators, as newly found non-trivial materials and structures, possess topological phases beyond the conventional bulk-boundary correspondence. In previous studies, in-gap boundary states such as the corner states were regarded as conclusive evidence for the emergence of higher-order topological insulators. Here, we present an experimental observation of a photonic higher-order topological insulator with corner states embedded into the bulk spectrum, denoted as the higher-order topological bound states in the continuum. Especially, we propose and experimentally demonstrate a new way to identify topological corner states by exciting them separately from the bulk states with photonic quantum superposition states. Our results extend the topological bound states in the continuum into higher-order cases, providing an unprecedented mechanism to achieve robust and localized states in a bulk spectrum. More importantly, our experiments exhibit the advantage of using the time evolution of quantum superposition states to identify topological corner modes, which may shed light on future exploration between quantum dynamics and higher-order topological photonics.
Highlights
Topological phases, possessing intriguing bulk and edge properties, play an important role in understanding matter[1,2,3,4,5]
The characterizations of higherorder topological insulators (HOTIs) rely on the corner states and hinge states existing in the bandgap and are well separated from other states, which guarantees that the corner states can be independently excited
We show that the corner states lie inside the continuum and coexist with extended waves, even so, their existence is still closely related to the size of the bandgap which protects the HOTI against disorders
Summary
Topological phases, possessing intriguing bulk and edge properties, play an important role in understanding matter[1,2,3,4,5]. Higherorder topological insulators (HOTIs) have been proposed as a novel topological phase of matter with unconventional bulk-boundary correspondence[15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32], where an. The other one is the topological crystalline insulators with quantized bulk polarization, which is theoretically proposed by considering tight-binding models[22,23] and experimentally achieved in photonics[23,24,30,32] and phononics[25,26,27]. The characterizations of HOTIs rely on the corner states and hinge states existing in the bandgap and are well separated from other states, which guarantees that the corner states can be independently excited
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