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Applied Mathematics and Mechanics >

2020 , Vol. 41 >Issue 10: 1447 - 1460

DOI: https://doi.org/10.1007/s10483-020-2660-8

Articles

Shear-horizontal waves in periodic layered nanostructure with both nonlocal and interface effects

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  • 1. Institute of Engineering Mechanics, Beijing Jiaotong University, Beijing 100044, China;
    2. Department of Civil Engineering, University of Akron, Akron, OH 44325-3905, U.S.A.;
    3. Department of Engineering Mechanics, Shijiazhuang Tiedao University, Shijiazhuang 050043, China;
    4. Hebei Key Laboratory of Mechanics of Intelligent Materials and Structures, Shijiazhuang Tiedao University, Shijiazhuang 050043, China

Received date: 2020-05-24

  Revised date: 2020-07-10

  Online published: 2020-10-09

Supported by

Project supported by the National Natural Science Foundation of China (Nos. 11472182 and 11272222) and the China Scholarship Council (No. 201907090051)

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Abstract

The propagation of shear-horizontal (SH) waves in the periodic layered nanocomposite is investigated by using both the nonlocal integral model and the nonlocal differential model with the interface effect. Based on the transfer matrix method and the Bloch theory, the band structures for SH waves with both vertical and oblique incidences to the structure are obtained. It is found that by choosing appropriate interface parameters, the dispersion curves predicted by the nonlocal differential model with the interface effect can be tuned to be the same as those based on the nonlocal integral model. Thus, by propagating the SH waves vertically and obliquely to the periodic layered nanostructure, we could invert, respectively, the interface mass density and the interface shear modulus, by matching the dispersion curves. Examples are further shown on how to determine the interface mass density and the interface shear modulus in theory.

Key words: shear-horizontal (SH) wave; nonlocal theory; interface effect; nanostructure; integral model; differential model

Cite this article

Ru TIAN, Jinxi LIU, E. N. PAN, Yuesheng WANG . Shear-horizontal waves in periodic layered nanostructure with both nonlocal and interface effects[J]. Applied Mathematics and Mechanics, 2020 , 41(10) : 1447 -1460 . DOI: 10.1007/s10483-020-2660-8

References

[1] SIGALAS, M. M. and ECONOMOU, E. N. Elastic and acoustic wave band structure. Journal of Sound and Vibration, 158, 377-382(1992)
[2] KUSHWAHA, M. S., HALEVI, P., DOBRZYNSKI, L., and DJAFARI-ROUHANI, B. Acoustic band structure of periodic elastic composites. Physical Review Letters, 71(13), 2022-2025(1993)
[3] GUO, X., LIU, H., ZHANG, K., and DUAN, H. L. Dispersion relations of elastic waves in two-dimensional tessellated piezoelectric phononic crystals. Applied Mathematical Modelling, 56, 65-82(2018)
[4] ZHENG, H., ZHANG, C., and YANG, Z. A local radial basis function collocation method for band structure computation of 3D phononic crystals. Applied Mathematical Modelling, 77, 1954-1964(2020)
[5] WU, L. Y., WU, M. L., and CHEN, L. W. The narrow pass band filter of tunable 1D phononic crystals with a dielectric elastomer layer. Smart Materials and Structures, 18(1), 015011(2009)
[6] RONDA, S. and MONTERO DE ESPINOSA, F. Design of piezoelectric piston-like piezoelectric transducers based on a phononic crystal. Advances in Applied Ceramics, 117(3), 177-181(2017)
[7] CERVERA, F., SANCHIS, L., SÁNCHEZ-PÉREZ, J. V., MARTÍNEZ-SALA, R., RUBIO, C., MESEGUER, F., LÓPEZ, C., CABALLERO, D., and SÁNCHEZ-DEHESA, J. Refractive acoustic devices for airborne sound. Physical Review Letters, 88(2), 023902(2002)
[8] BENCHABANE, S., KHELIF, A., CHOUJAA, A., DJAFARI-ROUHANI, B., and LAUDE, V. Interaction of waveguide and localized modes in a phononic crystal. Europhysics Letters, 71(4), 570-575(2005)
[9] WONG, E. W., SHEEHAN, P. E., and LIEBER, C. M. Nanobeam mechanics:elasticity, strength, and toughness of nanorods and nanotubes. Science, 277(5334), 1971-1975(1997)
[10] WANG, Z. L. and SONG, J. H. Piezoelectric nanogenerators based on zinc oxide nanowire arrays. Science, 312(5771), 242-246(2006)
[11] EBRAHIMI, F. and BARATI, M. R. Dynamic modeling of preloaded size-dependent nano-crystalline nano-structures. Applied Mathematical and Mechanics (English Edition), 38(12), 1753-1772(2017) https://doi.org/10.1007/s10483-017-2291-8
[12] RAMPRASAD, R. and SHI, N. Scalability of phononic crystal heterostructures. Applied Physics Letters, 87(11), 101101(2005)
[13] FARAJPOUR, A., GHAYESH, M. H., and FAROKHI, H. A review on the mechanics of nanostructures. International Journal of Engineering Science, 133, 231-263(2018)
[14] TOUPIN, R. A. Elastic materials with couple-stresses. Archive for Rational Mechanics and Analysis, 11(1), 385-414(1962)
[15] MINDLIN, R. D. and TIERSTEN, H. F. Effects of couple-stresses in linear elasticity. Archive for Rational Mechanics and Analysis, 11(1), 415-448(1962)
[16] ERINGEN, A. C. Theory of Micropolar Elasticity, Springer, New York, 101-248(1999)
[17] MINDLIN, R. D. Second gradient of strain and surface-tension in linear elasticity. International Journal of Solids and Structures, 1(4), 417-438(1965)
[18] ERINGEN, A. C. and EDELEN, D. G. B. On nonlocal elasticity. International Journal of Engineering Science, 10, 233-248(1972)
[19] ERINGEN, A. C. On differential equations of nonlocal elasticity and solutions of screw dislocation and surface waves. Journal of Applied Physics, 54(9), 4703-4710(1983)
[20] LIM, C. W., ZHANG, G., and REDDY, J. N. A higher-order nonlocal elasticity and strain gradient theory and its applications in wave propagation. Journal of the Mechanics and Physics of Solids, 78, 298-313(2015)
[21] LU, L., GUO, X. M., and ZHAO, J. Z. Size-dependent vibration analysis of nanobeams based on the nonlocal strain gradient theory. International Journal of Engineering Science, 116, 12-24(2017)
[22] GURTIN, M. E. and MURDOCH, A. I. A continuum theory of elastic material surfaces. Archive for Rational Mechanics and Analysis, 57(4), 291-323(1975)
[23] GURTIN, M. E. and MURDOCH, A. I. Surface stress in solids. International Journal of Solids and Structures, 14(6), 431-440(1978)
[24] CHEN, A. L. and WANG, Y. S. Size-effect on band structures of nanoscale phononic crystals. Physica E:Low-dimensional Systems and Nanostructures, 44(1), 317-321(2011)
[25] CHEN, A. L., WANG, Y. S., KE, L. L., GUO, Y. F., and WANG, Z. D. Wave propagation in nanoscaled periodic layered structures. Journal of Computational and Theoretical Nanoscience, 10(10), 2427-2437(2013)
[26] CHEN, J. Y., GUO, J. H., and PAN, E. Wave propagation in magneto-electro-elastic multilayered plates with nonlocal effect. Journal of Sound and Vibration, 400, 550-563(2017)
[27] ZHANG, L. L., LIU, J. X., FANG, X. Q., and NIE, G. Q. Effects of surface piezoelectricity and nonlocal scale on wave propagation in piezoelectric nanoplates. European Journal of MechanicsA/Solids, 46, 22-29(2014)
[28] WU, B., ZHANG, C. L., CHEN, W. Q., and ZHANG, C. Surface effects on anti-plane shear waves propagating in magneto-electro-elastic nanoplates. Smart Materials and Structures, 24(9), 095017(2015)
[29] JIA, F., ZHANG, Z. C., ZHANG, H. B., FENG, X. Q., and GU, B. Shear horizontal wave dispersion in nanolayers with surface effects and determination of surface elastic constants. Thin Solid Films, 645, 134-138(2018)
[30] ZHU, F., PAN, E., QIAN, Z. H., and WANG, Y. Dispersion curves, mode shapes, stresses and energies of SH and Lamb waves in layered elastic nanoplates with surface/interface effect. International Journal of Engineering Science, 142, 170-184(2019)
[31] ERINGEN, A. C. Nonlocal Continuum Field Theories, Springer, New York (2002)
[32] SEITZ, F., TURNBULL, D., and EHRENREICH, H. Solid State Physics, Academic Press, New York (1968)
[33] MINDLIN, R. E. Progress in Applied Mechanics (the Prager Anniversary Volume), Macmillan, New York (1963)
[34] TIERSTEN, H. F. Elastic surface waves guided by thin films. Journal of Applied Physics, 40(2), 770-789(1969)
[35] SHENOY, V. B. Atomistic calculations of elastic properties of metallic FCC crystal surfaces. Physical Review B, 71, 094104(2005)
[36] HE, J. and ZHAO, J. L. Finite element simulations of surface effect on Rayleigh waves. AIP Advances, 8, 035006(2018)
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