10.22190/FUWLEP1702103C

103

114

In the paper the theoretical consideration of the acoustic metamaterials is given. Metamaterials, which are usually composite, are artificial materials whose properties differ from those observed in nature or in the constituent materials. Metamaterials which are suitable for acoustic wave absorption are presented. Acoustic absorber is a beam made of solid material connected with spring-mass subunits. The purpose of the subunits is to give a band gap where some frequencies of acoustic wave are stopped. Mathematical models for various types of connection of subunits in the metamaterial and absorber are discussed. Based on the analogy between electromagnetic and acoustic waves the concept of negative effective mass is introduced as a basic principle for modeling. Acoustic metamaterial beams based on one, two or multi-frequency vibration absorbers are discussed. Depending on connection of absorbers in the beam, the structure may absorb wave in one-direction (for example the longitudinal one) or waves in two directions (transversal and longitudinal). In the paper an overview of mathematical models and suggestions for further investigation are given.

mass-in-mass subunit, metamaterial structure, resonance properties, frequency band gap

L. Cveticanin, Gy. Mester, Theory of Acoustic Metamaterials and Metamaterial Beams: An Overview, Acta Polytechnica Hungarica, 13(7), 2016, 43-62.

L. Cveticanin, M. Zukovic, Negative effective mass in acoustic metamaterial with nonlinear mass-in-mass subsystems, Communications in Nonlinear Science and Numerical Simulation, accepted on 22nd March 2017.

H.H.Huang, C.T. Sun, G.I Huang, On the negative effective mass density in acoustic metamaterials, International Journal of Engineering Science 47, 610-617, 2009.

A. Santillan and S.I. Bazhevolnyi, V modes, Physics Review B, vol. 84, 064304, 2011.

A. Santillan and S.I. Bazhevolnyi, V modes, Physics Review B, vol. 89, 184301, 2014.

X. Li, C, Xue, L. Fau, S. Zhang, Z. Chen, J. Ding, H. Zhang, Simultaneous realization of negative group velocity, fast and slow acoustic waves in a metamaterial, Applied Physics Letters, 108, 231904, 2016.

P. Sheng, X.X. Zhang, Z. Liu, C.T. Chan, Locally resonant sonic materials, Physica B, 338, 201-205, 2003.

P. Sheng, J. Mei, Z. Liu, W. Wen, Dynamic mass density and acoustic metamaterials, Physica B, vol. 394, pp. 256-261, 2007.

G.W. Milton, New metamaterials with macroscopic behavior outside that of continuum elastodynamics, New Journal of Physics, 9, 359, 2007.

Z. Liu, X. Zhang, Y. Mao, Y.Y. Zhu, Z. Yang, C.T. Chan, P. Sheng, Locally resonant sonic materials, Science, 289, 1734-1736, 2000.

Z. Liu, C.T. Chan, P. Sheng, Analytic model of phononic crystals with local resonances, Physical Review B, 71, 014103, 2005.

A. Avila, G. Griso, B. Miara, Bandes phononiques interdites en elasticite linearisee, Physics Review E, 340, 933-938, 2005.

G.W. Milton, J.R. Willis, On modifications of Newton’s second law and linear continuum elastodynamics, Proceedings of the Royal Society A, 463, 855-880, 2007.

R. Zhu, X.N. Liu, G.K. Hu, C.T. Sun, G.L. Huang, A chiral elastic metamaterial beam for broadband vibration suppression, Journal of Sound and Vibration 333, 2759-2773, 2014.