This repo contains MATLAB codes for some papers in the field of acoustic metamaterials.
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Cai, X., Guo, Q., Hu, G., & Yang, J. (2014). Ultrathin low-frequency sound absorbing panels based on coplanar spiral tubes or coplanar Helmholtz resonators. Applied Physics Letters, 105(12), 121901.
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Craggs, A., & Hildebrandt, J. G. (1986). The normal incidence absorption coefficient of a matrix of narrow tubes with constant cross-section. Journal of sound and vibration, 105(1), 101-107.
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Dupont, T., Leclaire, P., Sicot, O., Gong, X. L., & Panneton, R. (2011). Acoustic properties of air-saturated porous materials containing dead-end porosity. Journal of applied physics, 110(9), 094903.
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Huang, S., Fang, X., Wang, X., Assouar, B., Cheng, Q., & Li, Y. (2018). Acoustic perfect absorbers via spiral metasurfaces with embedded apertures. Applied Physics Letters, 113(23), 233501.
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Komkin, A. I., Mironov, M. A., & Bykov, A. I. (2017). Sound absorption by a Helmholtz resonator. Acoustical Physics, 63(4), 385-392.
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Leclaire, P., Umnova, O., Dupont, T., & Panneton, R. (2015). Acoustical properties of air-saturated porous material with periodically distributed dead-end pores. the Journal of the Acoustical Society of America, 137(4), 1772-1782.
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Li, Y., & Assouar, B. M. (2016). Acoustic metasurface-based perfect absorber with deep subwavelength thickness. Applied Physics Letters, 108(6), 063502.
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Salissou, Y., Panneton, R., & Doutres, O. (2012). Complement to standard method for measuring normal incidence sound transmission loss with three microphones. The Journal of the Acoustical Society of America, 131(3), EL216-EL222.
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Song, S. Y., Yang, X. H., Xin, F. X., Ren, S. W., & Lu, T. J. (2017). Modeling of roughness effects on acoustic properties of micro-slits. Journal of Physics D: Applied Physics, 50(23), 235303.