Realization of quasicrystalline quadrupole topological insulators in electrical circuits

TL;DR

This paper reports the experimental realization of aperiodic-quasicrystalline quadrupole topological insulators in electrical circuits, demonstrating localized corner modes and their robustness, expanding the study of topological phases in non-periodic structures.

Contribution

The study introduces a novel implementation of quadrupole topological insulators in aperiodic quasicrystalline structures using electrical circuits, which was not previously demonstrated.

Findings

Observation of spectrally and spatially localized corner modes.

Corner modes appear as topological boundary resonances in impedance spectra.

Robustness of corner modes confirmed in the circuit.

Abstract

Quadrupole topological insulators are a new class of topological insulators with quantized quadrupole moments, which support protected gapless corner states. The experimental demonstrations of quadrupole-topological insulators were reported in a series of artificial materials, such as photonic crystals, acoustic crystals, and electrical circuits. In all these cases, the underlying structures have discrete translational symmetry and thus are periodic. Here we experimentally realize two-dimensional aperiodic-quasicrystalline quadrupole-topological insulators by constructing them in electrical circuits, and observe the spectrally and spatially localized corner modes. In measurement, the modes appear as topological boundary resonances in the corner impedance spectra. Additionally, we demonstrate the robustness of corner modes on the circuit. Our circuit design may be extended to study topological phases in higher-dimensional aperiodic structures.