A General Framework of Bound States in the Continuum in an Open Acoustic Resonator

TL;DR

This paper introduces a versatile framework for creating bound states in the continuum (BICs) in open acoustic resonators, enabling high-Q resonances and tunable mode profiles for advanced acoustic device applications.

Contribution

It presents a general method to construct Friedrich-Wintgen and accidental BICs in coupled acoustic systems, with experimental validation and potential for device design.

Findings

Achieved FW BICs with arbitrary degenerate resonances.

Engineered eigenmode profiles by adjusting waveguide position.

Experimentally verified BICs in 3D coupled resonator systems.

Abstract

Bound states in the continuum (BICs) provide a viable way of achieving high-Q resonances in both photonics and acoustics. In this work, we proposed a general method of constructing Friedrich-Wintgen (FW) BICs and accidental BICs in a coupled acoustic waveguide-resonator system. We demonstrated that FW BICs can be achieved with arbitrary two degenerate resonances in a closed resonator regardless of whether they have the same or opposite parity. Moreover, their eigenmode profiles can be arbitrarily engineered by adjusting the position of attached waveguide. That suggests an effective way of continuous switching the nature of BIC from FW BIC to symmetry-protected BIC or accidental BICs. Also, such BICs are sustained in the coupled waveguide-resonator system with shapes such as rectangle, ellipse, and rhomboid. These interesting phenomena are well explained by the two-level effective non Hermitian Hamiltonian, where two strongly coupled degenerate modes play a major role in forming such FW BICs. Besides, we found that such an open system also supports accidental BICs in geometry space instead of momentum space via tuning the position of attached waveguide, which are attributed to the quenched coupling between the waveguide and eigenmodes of the closed cavity. Finally, we fabricated a series of 3D coupled-resonator-waveguide and experimentally verified the existence of FW BICs and accidental BICs by measuring the transmission spectra. Our results complement the current BIC library in acoustics and provide new routes for designing novel acoustic devices, such as in acoustic absorbers, filters and sensors.