A Modal Decomposition Approach to Topological Wave Propagation

TL;DR

This paper introduces a modal decomposition approach to analyze topological wave propagation, enabling accurate modeling of finite systems and prediction of wave dynamics considering bandwidth and damping effects.

Contribution

It develops a modal basis framework for topological waves, providing reduced-order models that capture finite-size and bandwidth effects in topological systems.

Findings

Topological waves are dominated by a small subset of localized modes.

The modal approach accurately predicts group velocity and edge-to-bulk transitions.

The method accounts for damping and finite bandwidth in practical systems.

Abstract

The characteristics of topologically protected wave propagation is typically predicted via the band structure of the primitive unit cell, using Berry curvature to predict localized interface or boundary states (as well as their degree of localization), and the dispersion relation to predict propagating group velocity. However, practical systems are finite in size and are driven by excitation with a finite bandwidth as guaranteed by the Fourier uncertainty principle. Hence, the dynamics predicted by the ideal infinite systems driven at a given frequency deviate from practical topological systems driven across a finite bandwidth. In this work, we demonstrate that the propagating topological waves in a valley Hall system can be interpreted using the underlying linear degenerate modal basis. We show that only a small subset of closely spaced modes with the appropriate phase differences comprise the topological waves, which enables the construction of analytical reduced-order models that accurately capture the topological wave. This result is related to the sparse density of the modal spectrum inside the topological band gap, which allows for the energy to be carried nearly completely by a narrow band of spectrally isolated eigenmodes that are spatially localized along the domain boundary. This finding is subsequently employed to predict the true group velocity of propagating topological waves with respect to input signal bandwidth and frequency by matching each active mode to corresponding band locations of the supercell dispersion diagram describing the semi-infinite system. Moreover, we demonstrate that damped topological waves may be studied within the framework of modal superposition by utilizing the damped modal spectrum to characterize the variation topological wave group velocity and predict edge-to-bulk transitions.