RESONANT MODAL APPROXIMATION OF TIME-DOMAIN ELASTIC SCATTERING FROM NANO-BUBBLES IN ELASTIC MATERIALS

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Original languageEnglish
Pages (from-to)713-751
Journal / PublicationMultiscale Modeling and Simulation
Volume22
Issue number2
Online published12 Apr 2024
Publication statusPublished - Jun 2024

Abstract

This paper is devoted to establishing the resonant modal expansion of the low-frequency part of the scattered field for acoustic bubbles embedded in elastic materials. Due to the nanobubble with damping, the Minnaert resonance can be induced at certain discrete resonant frequencies, which forms the fundamental basis of effectively constructing elastic metamaterials via the composite material theory. There are two major contributions in this work. First, we ansatz a special form of the density, approximate the incident field with a finite number of modes, and then obtain an expansion with a finite number of modes for the acoustic-elastic wave scattering in the time-harmonic regime. Second, we show that the low-frequency part of the scattered field in the time domain can be well approximated by using the modal expansion with sharp error estimates. Interestingly, we find that the 0th mode is the main contribution to reconstruct the information of the low-frequency part of the scattered field. © 2024 Society for Industrial and Applied Mathematics Publications. All rights reserved.

Research Area(s)

  • bubbly elastic medium, Minnaert resonance, modal analysis, Neumann-Poincaré operator, time domain