Open AccessAcoustic cloaking by a near-zero-index phononic crystal
Author(s) -
LiYang Zheng,
Ying Wu,
Xu Ni,
ZeGuo Chen,
MingHui Lu,
YanFeng Chen
Publication year - 2014
Publication title -
applied physics letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.182
H-Index - 442
eISSN - 1077-3118
pISSN - 0003-6951
DOI - 10.1063/1.4873354
Subject(s) - materials science , refractive index , cloaking , brillouin zone , condensed matter physics , optics , resonance (particle physics) , acoustic resonance , brillouin scattering , effective mass (spring–mass system) , acoustic wave , dispersion relation , scattering , acoustic dispersion , dispersion (optics) , metamaterial , physics , optoelectronics , classical mechanics , resonator , laser , particle physics
Zero-refractive-index materials may lead to promising applications in various fields. Here, we design and fabricate a near Zero-Refractive-Index (ZRI) material using a phononic crystal (PC) composed of a square array of densely packed square iron rods in air. The dispersion relation exhibits a nearly flat band across the Brillouin zone at the reduced frequency f = 0.5443c/a, which is due to Fabry-Perot (FP) resonance. By using a retrieval method, we find that both the effective mass density and the reciprocal of the effective bulk modulus are close to zero at frequencies near the flat band. We also propose an equivalent tube network model to explain the mechanisms of the near ZRI effect. This FP-resonance-induced near ZRI material offers intriguing wave manipulation properties. We demonstrate both numerically and experimentally its ability to shield a scattering obstacle and guide acoustic waves through a bent structure
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