Topology optimization of chiral metamaterials with application to underwater sound insulation

doi:10.1007/s10483-024-3162-8

Abstract

Abstract:

Chiral metamaterials have been proven to possess many appealing mechanical phenomena, such as negative Poisson's ratio, high-impact resistance, and energy absorption. This work extends the applications of chiral metamaterials to underwater sound insulation. Various chiral metamaterials with low acoustic impedance and proper stiffness are inversely designed using the topology optimization scheme. Low acoustic impedance enables the metamaterials to have a high and broadband sound transmission loss (STL), while proper stiffness guarantees its robust acoustic performance under a hydrostatic pressure. As proof-of-concept demonstrations, two specimens are fabricated and tested in a water-filled impedance tube. Experimental results show that, on average, over 95% incident sound energy can be isolated by the specimens in a broad frequency range from 1 kHz to 5 kHz, while the sound insulation performance keeps stable under a certain hydrostatic pressure. This work may provide new insights for chiral metamaterials into the underwater applications with sound insulation.

Key words: chiral metamaterial, topology optimization, underwater sound insulation, low acoustic impedance, sound transmission loss (STL)

2010 MSC Number:

74J20

Chao WANG, Honggang ZHAO, Yang WANG, Jie ZHONG, Dianlong YU, Jihong WEN. Topology optimization of chiral metamaterials with application to underwater sound insulation. Applied Mathematics and Mechanics (English Edition), 2024, 45(7): 1119-1138.

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References 49

1	WU, K., LIU, J., DING, Y., WANG, W., LIANG, B., and CHENG, J. Metamaterial-based real-time communication with high information density by multipath twisting of acoustic wave. Nature Communications, 13, 5171 (2022)
2	WANG, W., HU, C., NI, J., DING, Y., WENG, J., LIANG, B., QIU, C. W., and CHENG, J. C. Efficient and high-purity sound frequency conversion with a passive linear metasurface. Advanced Science, 9, 2203482 (2022)
3	REINHALL, P. G., and DAHL, P. H. Underwater Mach wave radiation from impact pile driving: theory and observation. The Journal of the Acoustical Society of America, 130, 1209- 1216 (2011)
4	AZEVEDO VASCONCELOS, A. C., VALIYA VALAPPIL, S., SCHOTT, D., JOVANOVA, J., and ARAGÓN, A. M. A metamaterial-based interface for the structural resonance shielding of impact-driven offshore monopiles. Engineering Structures, 300, 117261 (2024)
5	LEROY, V., STRYBULEVYCH, A., LANOY, M., LEMOULT, F., TOURIN, A., and PAGE, J. H. Super-absorption of acoustic waves with bubble meta-screens. Physical Review B, 91, 020301 (2015)
6	YANG, H., XIAO, Y., ZHAO, H., ZHONG, J., and WEN, J. On wave propagation and attenuation properties of underwater acoustic screens consisting of periodically perforated rubber layers with metal plates. Journal of Sound and Vibration, 444, 21- 34 (2019)
7	LANOY, M., GUILLERMIC, R. M., STRYBULEVYCH, A., and PAGE, J. H. Broadband coherent perfect absorption of acoustic waves with bubble meta-screens. Applied Physics Letters, 113 (17), 171901- 171907 (2018)
8	WANG, Y., ZHAO, H., YANG, H., LIU, J., YU, D., and WEN, J. Topological design of lattice materials with application to underwater sound insulation. Mechanical Systems and Signal Processing, 171, 108911 (2022)
9	GAO, N., DONG, Z., MAK, H. Y., and SHENG, P. Manipulation of low-frequency sound with a tunable active metamaterial panel. Physical Review Applied, 17 (4), 044037 (2022)
10	HOPKINS, C. Sound Insulation, Butterworth-Heinemann, Oxford (2007)
11	CHEN, Y., ZHENG, M., LIU, X., BI, Y., SUN, Z., XIANG, P., YANG, J., and HU, G. Broadband solid cloak for underwater acoustics. Physical Review B, 95 (18), 180101- 180104 (2017)
12	SHARMA, G. S., SKVORTSOV, A., MACGILLIVRAY, I., and KESSISSOGLOU, N. Sound transmission through a periodically voided soft elastic medium submerged in water. Wave Motion, 70, 101- 112 (2017)
13	CALVO, D. C., THANGAWNG, A. L., LAYMAN, C. N., J, R., CASALINI, R., and OTHMAN, S. F. Underwater sound transmission through arrays of disk cavities in a soft elastic medium. The Journal of the Acoustical Society of America, 138 (4), 2537- 2547 (2015)
14	LEROY, V., STRYBULEVYCH, A., SCANLON, M. G., and PAGE, J. H. Transmission of ultrasound through a single layer of bubbles. The European Physical Journal E, 29 (1), 123- 130 (2009)
15	ZHONG, H., TIAN, Y., GAO, N., LU, K., and WU, J. Ultra-thin composite underwater honeycomb-type acoustic metamaterial with broadband sound insulation and high hydrostatic pressure resistance. Composite Structures, 277, 114603 (2021)
16	CHEN, Y., ZHAO, B., LIU, X., and HU, G. Highly anisotropic hexagonal lattice material for low frequency water sound insulation. Extreme Mechanics Letters, 40, 100916 (2020)
17	WANG, Y., ZHAO, H., YANG, H., ZHANG, H., LI, T., WANG, C., LIU, J., ZHONG, J., YU, D., and WEN, J. Acoustically soft and mechanically robust hierarchical metamaterials in water. Physical Review Applied, 20 (5), 054015 (2023)
18	WU, W., HU, W., QIAN, G., LIAO, H., XU, X., and BERTO, F. Mechanical design and multifunctional applications of chiral mechanical metamaterials: a review. Materials & Design, 180, 107950 (2019)
19	LIU, X. N., HUANG, G. L., and HU, G. K. Chiral effect in plane isotropic micropolar elasticity and its application to chiral lattices. Journal of the Mechanics and Physics of Solids, 60 (11), 1907- 1921 (2012)
20	WANG, J., YANG, Q., WEI, Y., and TAO, R. A novel chiral metamaterial with multistability and programmable stiffness. Smart Materials and Structures, 30 (6), 65006 (2021)
21	YIN, Y., ZHAO, Z., and LI, Y. Theoretical and experimental research on anisotropic and nonlinear mechanics of periodic network materials. Journal of the Mechanics and Physics of Solids, 152, 104458 (2021)
22	FU, M., LIU, F., and HU, L. A novel category of 3D chiral material with negative Poisson's ratio. Composites Science and Technology, 160 (26), 111- 118 (2018)
23	WANG, X., QIN, R., LU, J., HUANG, M., ZHANG, X., and CHEN, B. Laser additive manufacturing of hierarchical multifunctional chiral metamaterial with distinguished damage-resistance and low-frequency broadband sound-absorption capabilities. Materials & Design, 238, 112659 (2024)
24	QI, D., LU, Q., HE, C., LI, Y., WU, W., and XIAO, D. Impact energy absorption of functionally graded chiral honeycomb structures. Extreme Mechanics Letters, 32, 100568 (2019)
25	SPADONI, A., RUZZENE, M., GONELLA, S., and SCARPA, F. Phononic properties of hexagonal chiral lattices. Wave Motion, 46 (7), 435- 450 (2009)
26	SPADONI, A., and RUZZENE, M. Structural and acoustic behavior of chiral truss-core beams. Journal of Vibration and Acoustics-Transactions of the ASME, 128 (5), 616- 626 (2006)
27	AN, X., LAI, C., HE, W., and FAN, H. Three-dimensional chiral meta-plate lattice structures for broad band vibration suppression and sound absorption. Composites Part B: Engineering, 224, 109232 (2021)
28	YANG, H., CHENG, S., LI, X., YAN, Q., WANG, B., XIN, Y., SUN, Y., DING, Q., YAN, H., LI, Y., and ZHAO, Q. Study on bandgap and vibration attenuation mechanism of novel chiral lattices. Physica B: Condensed Matter, 651, 414596 (2023)
29	LI, Z., ZHAI, W., LI, X., YU, X., GUO, Z., and WANG, Z. Additively manufactured dual-functional metamaterials with customisable mechanical and sound-absorbing properties. Virtual and Physical Prototyping, 17 (4), 864- 880 (2022)
30	BENDSØE, M. P., and SIGMUND, O. Topology Optimization: Theory, Method and Applications, Springer Berlin, Heidelberg (2003)
31	DONG, H. W., ZHAO, S. D., MIAO, X. B., SHEN, C., and CHENG, L. Customized broadband pentamode metamaterials by topology optimization. Journal of the Mechanics and Physics of Solids, 152 (2), 104407 (2021)
32	DONG, H., ZHAO, S., OUDICH, M., SHEN, C., ZHANG, C., CHENG, L., WANG, Y., and FANG, D. Reflective metasurfaces with multiple elastic mode conversions for broadband underwater sound absorption. Physical Review Applied, 17 (4), 044013 (2022)
33	KIM, K. H., and YOON, G. H. Acoustic topology optimization using moving morphable components in neural network-based design. Structural and Multidisciplinary Optimization, 65 (2), 47 (2022)
34	BOKHARI, A. H., MOUSAVI, A., NIU, B., and WADBRO, E. Topology optimization of an acoustic diode?. Structural and Multidisciplinary Optimization, 63 (6), 2739- 2749 (2021)
35	ZHENG, W., YANG, T., HUANG, Q., and HE, Z. Topology optimization of PCLD on plates for minimizing sound radiation at low frequency resonance. Structural and Multidisciplinary Optimization, 53 (6), 1231- 1242 (2016)
36	LU, L., YAMAMOTO, T., OTOMORI, M., YAMADA, T., IZUI, K., and NISHIWAKI, S. Topology optimization of an acoustic metamaterial with negative bulk modulus using local resonance. Finite Elements in Analysis and Design, 72, 1- 12 (2013)
37	CHRISTIANSEN, R. E., and SIGMUND, O. Experimental validation of systematically designed acoustic hyperbolic meta material slab exhibiting negative refraction. Applied Physics Letters, 109 (10), 101905 (2016)
38	WANG, G., HU, J., XIANG, L., SHI, M., and LUO, G. Topology-optimized ventilation barrier for mid-to-high frequency ultrabroadband sound insulation. Applied Acoustics, 202, 109145 (2023)
39	ZHANG, W., YUAN, J., ZHANG, J., and GUO, X. A new topology optimization approach based on moving morphable components (MMC) and the ersatz material model. Structural and Multidisciplinary Optimization, 53 (6), 1243- 1260 (2016)
40	SHA, W., HU, R., XIAO, M., CHU, S., ZHU, Z., QIU, C., and GAO, L. Topology-optimized thermal metamaterials traversing full-parameter anisotropic space. NPJ Computational Materials, 8 (1), 1- 10 (2022)
41	BENDSØE, M. P. Optimal shape design as a material distribution problem. Structural and Multidisciplinary Optimization, 1 (4), 193- 202 (1989)
42	BLAISE, B., and AN, X. Filters in topology optimization. International Journal for Numerical Methods in Engineering, 50 (9), 2143- 2158 (2001)
43	WANG, F., LAZAROV, B. S., and SIGMUND, O. On projection methods, convergence and robust formulations in topology optimization. Structural and Multidisciplinary Optimization, 43 (6), 767- 784 (2011)
44	SVANBERG, K. A class of globally convergent optimization methods based on conservative convex separable approximations. SIAM Journal on Optimization, 12 (2), 555- 573 (2002)
45	CHENG, G., CAI, Y., and XU, L. Novel implementation of homogenization method to predict effective properties of periodic materials. Acta Mechanica Sinica, 29 (4), 550- 556 (2013)
46	ZHAO, B., WANG, D., ZHOU, P., LIU, X., and HU, G. Design of load-bearing materials for isolation of low-frequency waterborne sound. Physical Review Applied, 17 (3), 034065 (2022)
47	WANG, K., CAI, M., ZHOU, P., and HU, G. Homogenization in a simpler way: analysis and optimization of periodic unit cells with Cauchy-Born hypothesis. Structural and Multidisciplinary Optimization, 64 (6), 3911- 3935 (2021)
48	HASHIN, Z., and SHTRIKMAN, S. A variational approach to the theory of the elastic behaviour of multiphase materials. Journal of the Mechanics and Physics of Solids, 11 (2), 127- 140 (1963)
49	ASTM E2611-09. Standard Test Method for Measurement of Normal Incidence Sound Transmission of Acoustical Materials Based on Transfer Matrix Method, American Society for Testing and Materials, New York (2009)

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