参考文献
[ 1 ]
Kinsler LE, Frey AR, Coppens AB, Sanders JV. Fundamentals of acoustics. 4th ed. Hoboken: John Wiley & Sons, Inc.; 2000.
[ 2 ]
Schriemer HP, Cowan ML, Page JH, Sheng P, Liu Z, Weitz DA. Energy velocity of diffusing waves in strongly scattering media. Phys Rev Lett 1997;79(17):3166‒9.
链接1
[ 3 ]
Kushwaha MS, Halevi P, Dobrzynski L, Djafari-Rouhani B. Acoustic band structure of periodic elastic composites. Phys Rev Lett 1993;71(13):2022‒5.
链接1
[ 4 ]
Sigalas M, Economou EN. Band structure of elastic waves in two dimensional systems. Solid State Commun 1993;86(3):141‒3.
链接1
[ 5 ]
Martínez-Sala R, Sancho J, Sánchez JV, Gómez V, Llinares J, Meseguer F. Sound attenuation by sculpture. Nature 1995;378(6554):241.
链接1
[ 6 ]
Yang S, Page JH, Liu Z, Cowan ML, Chan CT, Sheng P. Focusing of sound in a 3D phononic crystal. Phys Rev Lett 2004;93(2):024301.
链接1
[ 7 ]
Ke M, Liu Z, Qiu C, Wang W, Shi J, Wen W, et al. Negative-refraction imaging with two-dimensional phononic crystals. Phys Rev B 2005;72(6):064306.
链接1
[ 8 ]
Lu MH, Liu XK, Feng L, Li J, Huang CP, Chen YF, et al. Extraordinary acoustic transmission through a 1D grating with very narrow apertures. Phys Rev Lett 2007;99(17):174301.
链接1
[ 9 ]
Qiu C, Liu Z. Acoustic directional radiation and enhancement caused by bandedge states of two-dimensional phononic crystals. Appl Phys Lett 2006;89(6):063106.
链接1
[10]
Liu Z, Zhang X, Mao Y, Zhu YY, Yang Z, Chan CT, et al. Locally resonant sonic materials. Science 2000;289(5485):1734‒6.
链接1
[11]
Ho KM, Cheng CK, Yang Z, Zhang XX, Sheng P. Broadband locally resonant sonic shields. Appl Phys Lett 2003;83(26):5566‒8.
链接1
[12]
Sainidou R, Djafari-Rouhani B, Pennec Y, Vasseur JO. Locally resonant phononic crystals made of hollow spheres or cylinders. Phys Rev B 2006;73(2):024302.
链接1
[13]
Yang M, Sheng P. Sound absorption structures: from porous media to acoustic metamaterials. Annu Rev Mater Res 2017;47(1):83‒114.
链接1
[14]
Farhat M, Enoch S, Guenneau S, Movchan AB. Broadband cylindrical acoustic cloak for linear surface waves in a fluid. Phys Rev Lett 2008;101(13):134501.
链接1
[15]
Torrent D, Sánchez-Dehesa J. Acoustic cloaking in two dimensions: a feasible approach. New J Phys 2008;10(6):063015.
链接1
[16]
Zhang S, Yin L, Fang N. Focusing ultrasound with an acoustic metamaterial network. Phys Rev Lett 2009;102(19):194301.
链接1
[17]
Li Y, Yu G, Liang B, Zou X, Li G, Cheng S, et al. Three-dimensional ultrathin planar lenses by acoustic metamaterials. Sci Rep 2014;4(1):6830.
链接1
[18]
Lee SH, Park CM, Seo YM, Kim CK. Reversed Doppler effect in double negative metamaterials. Phys Rev B 2010;81(24):241102.
链接1
[19]
Li Y, Jiang X, Liang B, Cheng J, Zhang L. Metascreen-based acoustic passive phased array. Phys Rev Appl 2015;4(2):024003.
链接1
[20]
Cheng Y, Zhou C, Yuan BG, Wu DJ, Wei Q, Liu XJ. Ultra-sparse metasurface for high reflection of low-frequency sound based on artificial Mie resonances. Nat Mater 2015;14(10):1013‒9.
链接1
[21]
Xie Y, Wang W, Chen H, Konneker A, Popa BI, Cummer SA. Wavefront modulation and subwavelength diffractive acoustics with an acoustic metasurface. Nat Commun 2014;5(1):5553.
链接1
[22]
Ge H, Xu XY, Liu L, Xu R, Lin ZK, Yu SY, et al. Observation of acoustic skyrmions. Phys Rev Lett 2021;127(14):144502.
链接1
[23]
Wang Y, Zhao H, Yang H, Zhong J, Zhao D, Lu Z, et al. A tunable soundabsorbing metamaterial based on coiled-up space. J Appl Phys 2018;123(18):185109.
链接1
[24]
Song GY, Cheng Q, Huang B, Dong HY, Cui TJ. Broadband fractal acoustic metamaterials for low-frequency sound attenuation. Appl Phys Lett 2016;109(13):131901.
链接1
[25]
Liang Z, Li J. Extreme acoustic metamaterial by coiling up space. Phys Rev Lett 2012;108(11):114301.
链接1
[26]
Yu SY, Sun XC, Ni X, Wang Q, Yan XJ, He C, et al. Surface phononic graphene. Nat Mater 2016;15(12):1243‒7.
链接1
[27]
Torrent D, Sánchez-Dehesa J. Acoustic analogue of graphene: observation of Dirac cones in acoustic surface waves. Phys Rev Lett 2012;108(17):174301.
链接1
[28]
Zhang X, Liu Z. Extremal transmission and beating effect of acoustic waves in two-dimensional sonic crystals. Phys Rev Lett 2008;101(26):264303.
链接1
[29]
Chen ZG, Wu Y. Tunable topological phononic crystals. Phys Rev Appl 2016;5(5):054021.
链接1
[30]
Ni X, He C, Sun XC, Liu X, Lu MH, Feng L, et al. Topologically protected oneway edge mode in networks of acoustic resonators with circulating air flow. New J Phys 2015;17(5):053016.
链接1
[31]
Zhang X, Wang HX, Lin ZK, Tian Y, Xie B, Lu MH, et al. Second-order topology and multidimensional topological transitions in sonic crystals. Nat Phys 2019;15(6):582‒8.
链接1
[32]
Christensen J, Willatzen M, Velasco VR, Lu MH. Parity-time synthetic phononic media. Phys Rev Lett 2016;116(20):207601.
链接1
[33]
Zhu X, Ramezani H, Shi C, Zhu J, Zhang X. PT-symmetric acoustics. Phys Rev X 2014;4(3):031042.
链接1
[34]
Hu B, Zhang Z, Zhang H, Zheng L, Xiong W, Yue Z, et al. Non-Hermitian topological whispering gallery. Nature 2021;597(7878):655‒9.
链接1
[35]
Popa BI, Cummer SA. Non-reciprocal and highly nonlinear active acoustic metamaterials. Nat Commun 2014;5(1):3398.
链接1
[36]
Fleury R, Sounas DL, Sieck CF, Haberman MR, Alù A. Sound isolation and giant linear nonreciprocity in a compact acoustic circulator. Science 2014;343(6170):516‒9.
链接1
[37]
Liao G, Luan C, Wang Z, Liu J, Yao X, Fu J. Acoustic metamaterials: a review of theories, structures, fabrication approaches, and applications. Adv Mater Technol 2021;6(5):2000787.
链接1
[38]
Zangeneh-Nejad F, Fleury R. Active times for acoustic metamaterials. Rev Phys 2019;4:100031.
链接1
[39]
Wu Y, Yang M, Sheng P. Perspective: acoustic metamaterials in transition. J Appl Phys 2018;123(9):090901.
链接1
[40]
Ge H, Yang M, Ma C, Lu MH, Chen YF, Fang N, et al. Breaking the barriers: advances in acoustic functional materials. Natl Sci Rev 2018;5(2):159‒82.
链接1
[41]
Cummer SA, Christensen J, Alù A. Controlling sound with acoustic metamaterials. Nat Rev Mater 2016;1(3):16001.
链接1
[42]
Lu MH, Feng L, Chen YF. Phononic crystals and acoustic metamaterials. Mater Today 2009;12(12):34‒42.
链接1
[43]
Muhammad LCW. From photonic crystals to seismic metamaterials: a review via phononic crystals and acoustic metamaterials. Arch Comput Methods Eng 2021;29:1137‒98.
链接1
[44]
Kumar S, Lee HP. The present and future role of acoustic metamaterials for architectural and urban noise mitigations. Acoustics 2019;1(3):590‒607.
链接1
[45]
Liu J, Guo H, Wang T. A review of acoustic metamaterials and phononic crystals. Crystals 2020;10(4):305.
链接1
[46]
Kumar S, Lee HP. Recent advances in active acoustic metamaterials. Int J Appl Mech 2019;11(8):1950081.
链接1
[47]
Allard J, Atalla N. Propagation of sound in porous media: modelling sound absorbing materials. 2nd ed. Chichester: John Wiley & Sons, Ltd.; 2009.
链接1
[48]
Yang Z, Mei J, Yang M, Chan NH, Sheng P. Membrane-type acoustic metamaterial with negative dynamic mass. Phys Rev Lett 2008;101(20):204301.
链接1
[49]
Mei J, Ma G, Yang M, Yang Z, Wen W, Sheng P. Dark acoustic metamaterials as super absorbers for low-frequency sound. Nat Commun 2012;3(1):756.
链接1
[50]
Yang M, Li Y, Meng C, Fu C, Mei J, Yang Z, et al. Sound absorption by subwavelength membrane structures: a geometric perspective. CR Mecanique 2015;343(12):635‒44.
链接1
[51]
Ma G, Yang M, Xiao S, Yang Z, Sheng P. Acoustic metasurface with hybrid resonances. Nat Mater 2014;13(9):873‒8.
链接1
[52]
Yang M, Meng C, Fu C, Li Y, Yang Z, Sheng P. Subwavelength total acoustic absorption with degenerate resonators. Appl Phys Lett 2015;107(10):104104.
链接1
[53]
Wei P, Croënne C, Tak Chu S, Li J. Symmetrical and anti-symmetrical coherent perfect absorption for acoustic waves. Appl Phys Lett 2014;104(12):121902.
链接1
[54]
Yang M, Ma G, Yang Z, Sheng P. Subwavelength perfect acoustic absorption in membrane-type metamaterials: a geometric perspective. EPJ Appl Metamat 2015;2:10.
链接1
[55]
Meng C, Zhang X, Tang ST, Yang M, Yang Z. Acoustic coherent perfect absorbers as sensitive null detectors. Sci Rep 2017;7(1):43574.
链接1
[56]
Wang X, Zhao H, Luo X, Huang Z. Membrane-constrained acoustic metamaterials for low frequency sound insulation. Appl Phys Lett 2016;108(4):041905.
链接1
[57]
Merkel A, Theocharis G, Richoux O, Romero-García V, Pagneux V. Control of acoustic absorption in one-dimensional scattering by resonant scatterers. Appl Phys Lett 2015;107(24):244102.
链接1
[58]
Richoux O, Achilleos V, Theocharis G, Brouzos I. Subwavelength interferometric control of absorption in three-port acoustic network. Sci Rep 2018;8(1):12328.
链接1
[59]
Groby JP, Lagarrigue C, Brouard B, Dazel O, Tournat V, Nennig B. Enhancing the absorption properties of acoustic porous plates by periodically embedding Helmholtz resonators. J Acoust Soc Am 2015;137(1):273‒80.
链接1
[60]
Huang S, Fang X, Wang X, Assouar B, Cheng Q, Li Y. Acoustic perfect absorbers via Helmholtz resonators with embedded apertures. J Acoust Soc Am 2019;145(1):254‒62.
链接1
[61]
Jiménez N, Romero-García V, Pagneux V, Groby JP. Quasiperfect absorption by subwavelength acoustic panels in transmission using accumulation of resonances due to slow sound. Phys Rev B 2017;95(1):014205.
链接1
[62]
Groby JP, Pommier R, Aurégan Y. Use of slow sound to design perfect and broadband passive sound absorbing materials. J Acoust Soc Am 2016;139(4):1660‒71.
链接1
[63]
Jiang X, Liang B, Li R, Zou X, Yin L, Cheng J. Ultra-broadband absorption by acoustic metamaterials. Appl Phys Lett 2014;105(24):243505.
链接1
[64]
Romero-García V, Theocharis G, Richoux O, Pagneux V. Use of complex frequency plane to design broadband and sub-wavelength absorbers. J Acoust Soc Am 2016;139(6):3395‒403.
链接1
[65]
Kim SR, Kim YH, Jang JH. A theoretical model to predict the low-frequency sound absorption of a helmholtz resonator array. J Acoust Soc Am 2006;119(4):1933‒6.
链接1
[66]
Liu CR, Wu JH, Chen X, Ma F. A thin low-frequency broadband metasurface with multi-order sound absorption. J Phys D Appl Phys 2019;52(10):105302.
链接1
[67]
Shen Y, Yang Y, Guo X, Shen Y, Zhang D. Low-frequency anechoic metasurface based on coiled channel of gradient cross-section. Appl Phys Lett 2019;114(8):083501.
链接1
[68]
Zhang C, Hu X. Three-dimensional single-port labyrinthine acoustic metamaterial: perfect absorption with large bandwidth and tunability. Phys Rev Appl 2016;6(6):064025.
链接1
[69]
Yang M, Chen S, Fu C, Sheng P. Optimal sound-absorbing structures. Mater Horiz 2017;4(4):673‒80.
链接1
[70]
Mak HY, Zhang X, Dong Z, Miura S, Iwata T, Sheng P. Going beyond the causal limit in acoustic absorption. Phys Rev Appl 2021;16(4):044062.
链接1
[71]
Sun M, Fang X, Mao D, Wang X, Li Y. Broadband acoustic ventilation barriers. Phys Rev Appl 2020;13(4):044028.
链接1
[72]
Leroy V, Strybulevych A, Lanoy M, Lemoult F, Tourin A, Page JH. Superabsorption of acoustic waves with bubble metascreens. Phys Rev B 2015;91(2):020301.
链接1
[73]
Ivansson SM. Sound absorption by viscoelastic coatings with periodically distributed cavities. J Acoust Soc Am 2006;119(6):3558‒67.
链接1
[74]
Ivansson SM. Numerical design of Alberich anechoic coatings with superellipsoidal cavities of mixed sizes. J Acoust Soc Am 2008;124(4):1974‒84.
链接1
[75]
Meng H, Wen J, Zhao H, Wen X. Optimization of locally resonant acoustic metamaterials on underwater sound absorption characteristics. J Sound Vibrat 2012;331(20):4406‒16.
链接1
[76]
Huang Z, Zhao S, Su M, Yang Q, Li Z, Cai Z, et al. Bioinspired patterned bubbles for broad and low-frequency acoustic blocking. ACS Appl Mater Interfaces 2020;12(1):1757‒64.
链接1
[77]
Duan M, Yu C, Xin F, Lu TJ. Tunable underwater acoustic metamaterials via quasi-Helmholtz resonance: from low-frequency to ultra-broadband. Appl Phys Lett 2021;118(7):071904.
链接1
[78]
Zhang Y, Pan J, Chen K, Zhong J. Subwavelength and quasi-perfect underwater sound absorber for multiple and broad frequency bands. J Acoust Soc Am 2018;144(2):648‒59.
链接1
[79]
Shi K, Jin G, Liu R, Ye T, Xue Y. Underwater sound absorption performance of acoustic metamaterials with multilayered locally resonant scatterers. Results Phys 2019;12:132‒42.
链接1
[80]
Naify CJ, Martin TP, Layman CN, Nicholas M, Thangawng AL, Calvo DC, et al. Underwater acoustic omnidirectional absorber. Appl Phys Lett 2014;104(7):073505.
链接1
[81]
Wang C, Li SD, Zheng WG, Huang QB. Acoustic absorption characteristics of new underwater omnidirectional absorber. Chin Phys Lett 2019;36 (4):044301.
链接1
[82]
Park CM, Park JJ, Lee SH, Seo YM, Kim CK, Lee SH. Amplification of acoustic evanescent waves using metamaterial slabs. Phys Rev Lett 2011;107(19):194301.
链接1
[83]
Li J, Fok L, Yin X, Bartal G, Zhang X. Experimental demonstration of an acoustic magnifying hyperlens. Nat Mater 2009;8(12):931‒4.
链接1
[84]
Pendry JB. Negative refraction makes a perfect lens. Phys Rev Lett 2000;85(18):3966‒9.
链接1
[85]
Zhang X, Liu Z. Superlenses to overcome the diffraction limit. Nat Mater 2008;7(6):435‒41.
链接1
[86]
Fang N, Lee H, Sun C, Zhang X. Sub-diffraction-limited optical imaging with a silver superlens. Science 2005;308(5721):534‒7.
链接1
[87]
Ambati M, Fang N, Sun C, Zhang X. Surface resonant states and superlensing in acoustic metamaterials. Phys Rev B 2007;75(19):195447.
链接1
[88]
Park JJ, Park CM, Lee KJB, Lee SH. Acoustic superlens using membrane-based metamaterials. Appl Phys Lett 2015;106(5):051901.
链接1
[89]
Kaina N, Lemoult F, Fink M, Lerosey G. Negative refractive index and acoustic superlens from multiple scattering in single negative metamaterials. Nature 2015;525(7567):77‒81.
链接1
[90]
Molerón M, Daraio C. Acoustic metamaterial for subwavelength edge detection. Nat Commun 2015;6(1):8037.
链接1
[91]
Ao X, Chan CT. Far-field image magnification for acoustic waves using anisotropic acoustic metamaterials. Phys Rev E 2008;77(2):025601.
链接1
[92]
Christensen J, García de Abajo FJ. Acoustic field enhancement and subwavelength imaging by coupling to slab waveguide modes. Appl Phys Lett 2010;97(16):164103.
链接1
[93]
Shen YX, Peng YG, Cai F, Huang K, Zhao DG, Qiu CW, et al. Ultrasonic superoscillation wave-packets with an acoustic meta-lens. Nat Commun 2019;10(1):3411.
链接1
[94]
García-Chocano VM, Christensen J, Sánchez-Dehesa J. Negative refraction and energy funneling by hyperbolic materials: an experimental demonstration in acoustics. Phys Rev Lett 2014;112(14):144301.
链接1
[95]
Shen C, Xie Y, Sui N, Wang W, Cummer SA, Jing Y. Broadband acoustic hyperbolic metamaterial. Phys Rev Lett 2015;115(25):254301.
链接1
[96]
Lemoult F, Fink M, Lerosey G. Acoustic resonators for far-field control of sound on a subwavelength scale. Phys Rev Lett 2011;107(6):064301.
链接1
[97]
Bai L, Dong HY, Song GY, Cheng Q, Huang B, Jiang WX, et al. Impedancematching wavefront-transformation lens based on acoustic metamaterials. Adv Mater Technol 2018;3(11):1800064.
链接1
[98]
Al Jahdali R, Wu Y. High transmission acoustic focusing by impedancematched acoustic meta-surfaces. Appl Phys Lett 2016;108(3):031902.
链接1
[99]
Peng S, He Z, Jia H, Zhang A, Qiu C, Ke M, et al. Acoustic far-field focusing effect for two-dimensional graded negative refractive-index sonic crystals. Appl Phys Lett 2010;96(26):263502.
链接1
[100]
Su X, Norris AN, Cushing CW, Haberman MR, Wilson PS. Broadband focusing of underwater sound using a transparent pentamode lens. J Acoust Soc Am 2017;141(6):4408‒17.
链接1
[101]
Chen J, Rao J, Lisevych D, Fan Z. Broadband ultrasonic focusing in water with an ultra-compact metasurface lens. Appl Phys Lett 2019;114(10):104101.
链接1
[102]
Ruan Y, Liang X, Wang Z, Wang T, Deng Y, Qu F, et al. 3-D underwater acoustic wave focusing by periodic structure. Appl Phys Lett 2019;114(8):081908.
链接1
[103]
Schurig D, Mock JJ, Justice BJ, Cummer SA, Pendry JB, Starr AF, et al. Metamaterial electromagnetic cloak at microwave frequencies. Science 2006;314(5801):977‒80.
链接1
[104]
Pendry JB, Schurig D, Smith DR. Controlling electromagnetic fields. Science 2006;312(5781):1780‒2.
链接1
[105]
Cummer SA, Popa BI, Schurig D, Smith DR, Pendry J, Rahm M, et al. Scattering theory derivation of a 3D acoustic cloaking shell. Phys Rev Lett 2008;100(2):024301.
链接1
[106]
Chen H, Chan C. Acoustic cloaking in three dimensions using acoustic metamaterials. Appl Phys Lett 2007;91(18):183518.
链接1
[107]
Cummer SA, Schurig D. One path to acoustic cloaking. New J Phys 2007;9(3):45.
链接1
[108]
Cheng Y, Yang F, Xu JY, Liu XJ. A multilayer structured acoustic cloak with homogeneous isotropic materials. Appl Phys Lett 2008;92(15):151913.
链接1
[109]
Popa BI, Zigoneanu L, Cummer SA. Experimental acoustic ground cloak in air. Phys Rev Lett 2011;106(25):253901.
链接1
[110]
Zigoneanu L, Popa BI, Cummer SA. Three-dimensional broadband omnidirectional acoustic ground cloak. Nat Mater 2014;13(4):352‒5.
链接1
[111]
Zhang S, Xia C, Fang N. Broadband acoustic cloak for ultrasound waves. Phys Rev Lett 2011;106(2):024301.
链接1
[112]
Li XF, Ni X, Feng L, Lu MH, He C, Chen YF. Tunable unidirectional sound propagation through a sonic-crystal-based acoustic diode. Phys Rev Lett 2011;106(8):084301.
链接1
[113]
Hasan MZ, Kane CL. Colloquium: topological insulators. Rev Mod Phys 2010;82(4):3045‒67.
链接1
[114]
Qi XL, Zhang SC. Topological insulators and superconductors. Rev Mod Phys 2011;83(4):1057‒110.
链接1
[115]
Zhang L, Ren J, Wang JS, Li B. Topological nature of the phonon Hall effect. Phys Rev Lett 2010;105(22):225901.
链接1
[116]
Li N, Ren J, Wang L, Zhang G, Hänggi P, Li B. Colloquium: phononics: manipulating heat flow with electronic analogs and beyond. Rev Mod Phys 2012;84(3):1045‒66.
链接1
[117]
Yang Z, Gao F, Shi X, Lin X, Gao Z, Chong Y, et al. Topological acoustics. Phys Rev Lett 2015;114(11):114301.
链接1
[118]
Xiao M, Ma G, Yang Z, Sheng P, Zhang ZQ, Chan CT. Geometric phase and band inversion in periodic acoustic systems. Nat Phys 2015;11(3):240‒4.
链接1
[119]
He C, Ni X, Ge H, Sun XC, Chen YB, Lu MH, et al. Acoustic topological insulator and robust one-way sound transport. Nat Phys 2016;12(12):1124‒9.
链接1
[120]
Zhang Z, Wei Q, Cheng Y, Zhang T, Wu D, Liu X. Topological creation of acoustic pseudospin multipoles in a flow-free symmetry-broken metamaterial lattice. Phys Rev Lett 2017;118(8):084303.
链接1
[121]
Zhu Z, Yan M, Pan J, Yang Y, Deng W, Lu J, et al. Acoustic valley spin Chern insulators. Phys Rev Appl 2021;16(1):014058.
链接1
[122]
Yang Z, Zhang B. Acoustic type-II Weyl nodes from stacking dimerized chains. Phys Rev Lett 2016;117(22):224301.
链接1
[123]
Shen C, Xu J, Fang NX, Jing Y. Anisotropic complementary acoustic metamaterial for canceling out aberrating layers. Phys Rev X 2014;4(4):041033.
链接1
[124]
Bok E, Park JJ, Choi H, Han CK, Wright OB, Lee SH. Metasurface for water-toair sound transmission. Phys Rev Lett 2018;120(4):044302.
链接1
[125]
Huang Z, Zhao S, Zhang Y, Cai Z, Li Z, Xiao J, et al. Tunable fluid-type metasurface for wide-angle and multifrequency water-air acoustic transmission. Research 2021;2021:9757943.
链接1
[126]
Huang Z, Zhao Z, Zhao S, Cai X, Zhang Y, Cai Z, et al. Lotus metasurface for wide-angle intermediate-frequency water-air acoustic transmission. ACS Appl Mater Interfaces 2021;13(44):53242‒51.
链接1
[127]
Ding Y, Statharas EC, Yao K, Hong M. A broadband acoustic metamaterial with impedance matching layer of gradient index. Appl Phys Lett 2017;110(24):241903.
链接1
[128]
Li Z, Yang DQ, Liu SL, Yu SY, Lu MH, Zhu J, et al. Broadband gradient impedance matching using an acoustic metamaterial for ultrasonic transducers. Sci Rep 2017;7(1):42863.
链接1
[129]
Liu C, Luo J, Lai Y. Acoustic metamaterials with broadband and wide-angle impedance matching. Phys Rev Mater 2018;2(4):045201.
链接1
[130]
Fernández-Marín AA, Jiménez N, Groby JP, Sánchez-Dehesa J, Romero-García V. Aerogel-based metasurfaces for perfect acoustic energy absorption. Appl Phys Lett 2019;115(6):061901.
链接1
[131]
Song K, Kim J, Hur S, Kwak JH, Lee SH, Kim T. Directional reflective surface formed via gradient-impeding acoustic meta-surfaces. Sci Rep 2016;6(1):32300.
链接1
[132]
Xie Y, Popa BI, Zigoneanu L, Cummer SA. Measurement of a broadband negative index with space-coiling acoustic metamaterials. Phys Rev Lett 2013;110(17):175501.
链接1