Elastic bound state in the continuum with perfect mode conversion

The partial or complete confinement of waves in an open system is omnipresent in nature and in wave-based materials and technology. Here, we theoretically analyze and experimentally observe the formation of a trapped mode with perfect mode conversion (TMPC) between flexural waves and longitudinal waves, by achieving a quasi-bound state in the continuum (BIC) in an open elastic wave system. The latter allows a quasi-BIC in a semi-infinite background plate when Fano resonance hybridizes flexural and longitudinal waves and balances their radiative decay rates. We demonstrate that when the Fabry-Pe ' rot resonance of the longitudinal wave is realized simultaneously, the TMPC formed by the elastic BIC approaches infinite quality factor. Furthermore, we show that quasi-BIC can be tuned continuously to BIC through the critical frequency of mode conversion, which offers the possibility of TMPC with an arbitrarily high quality factor. Our reported concept and physical mechanism open new routes to achieve perfect mode conversion with tunable high quality factor in elastic systems.

Automated summary

The study demonstrates the formation of a trapped mode with perfect mode conversion between flexural waves and longitudinal waves in an open elastic wave system. By achieving a quasi-bound state in the continuum, the researchers were able to approach infinite quality factor for the mode conversion. Additionally, they showed that the quality factor can be continuously tuned from quasi-BIC to BIC through the critical frequency of mode conversion, offering the possibility of achieving perfect mode conversion with an arbitrarily high quality factor.