Expanding the Bragg scattering bandgap of phononic crystals using acoustic black holes

In this paper, a phononic crystal with acoustic black hole (ABH) characteristics is designed based on the compression effect of ABHs on acoustic wavelengths. The simulation results show that the lower limit of the first bandgap of the phononic crystal with ABH is reduced by 127.8Hz, the upper limit is increased by 694.4Hz, and the bandgap width is increased by 822.2Hz compared with that of the phononic crystal without ABH. The mechanism of bandgap expansion is discussed based on the mechanism of bandgap formation and the acoustic modulation effect of the ABH. The influence of the geometric and material parameters of the ABH on the bandgap is analyzed. The ABHs offer a new way of optimizing phononic crystals, and this work can be used as a reference for their design.

Automated summary

This paper designs a phononic crystal with acoustic black hole (ABH) characteristics and discusses the mechanism of bandgap expansion and the factors influencing ABH. The results show that the phononic crystal with ABH has improved bandgap width and limits compared to the one without ABH.