Open AccessAnisotropic acoustic metafluid for underwater operation
Author(s) -
BogdanIoan Popa,
Wenqi Wang,
Adam Konneker,
Steven A. Cummer,
Charles A. Rohde,
Theodore P. Martin,
Gregory J. Orris,
Matthew D. Guild
Publication year - 2016
Publication title -
the journal of the acoustical society of america
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.619
H-Index - 187
eISSN - 1520-8524
pISSN - 0001-4966
DOI - 10.1121/1.4950754
Subject(s) - isotropy , anisotropy , materials science , bulk modulus , acoustics , shear modulus , shear (geology) , underwater , compressibility , inertial frame of reference , acoustic wave , metamaterial , modulus , mechanics , composite material , physics , optics , classical mechanics , geology , oceanography , optoelectronics
The paper presents a method to design and characterize mechanically robust solid acoustic metamaterials suitable for operation in dense fluids such as water. These structures, also called metafluids, behave acoustically as inertial fluids characterized by anisotropic mass densities and isotropic bulk modulus. The method is illustrated through the design and experimental characterization of a metafluid consisting of perforated steel plates held together by rubber coated magnetic spacers. The spacers are very effective at reducing the effective shear modulus of the structure, and therefore effective at minimizing the ensuing coupling between the shear and pressure waves inside the solid effective medium. Inertial anisotropy together with fluid-like acoustic behavior are key properties that bring transformation acoustics in dense fluids closer to reality.
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