Soil-expended seismic metamaterial with ultralow and wide bandgap

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

Externe Organisationen

  • Chongqing University
  • Nanjing University of Aeronautics and Astronautics
  • The University of Liverpool
  • Tongji University
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Details

OriginalspracheEnglisch
Aufsatznummer104601
FachzeitschriftMechanics of materials
Jahrgang180
Frühes Online-Datum1 März 2023
PublikationsstatusVeröffentlicht - Mai 2023

Abstract

The low-frequency wide-bandgap characteristics of the seismic metamaterial can suppress the propagation of vibrations and reduce the risk of extreme loadings such as earthquakes. The stringent requirement of lattice size extensively increawiths the cost of forming seismic metamaterial with general engineering materials. We design soil-expanded seismic metamaterial to reduce the scale restriction on artificial materials. Two types of soil-expanded lattice are created, and the bandgap characteristics for the lattice are obtained through the transfer matrix method. The propagation process for finite periodic lattice is simulated by the finite difference method in the time domain. It is found that the acceleration amplitudes in the wave propagation region are suppressed by 90% for the seismic metamaterial with rubber components. The response spectra further indicate that seismic metamaterials can reduce seismic risk in targeted areas.

ASJC Scopus Sachgebiete

Zitieren

Soil-expended seismic metamaterial with ultralow and wide bandgap. / Bai, Yongtao; Li, Xiaolei; Zhou, Xuhong et al.
in: Mechanics of materials, Jahrgang 180, 104601, 05.2023.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Bai Y, Li X, Zhou X, Li P, Beer M. Soil-expended seismic metamaterial with ultralow and wide bandgap. Mechanics of materials. 2023 Mai;180:104601. Epub 2023 Mär 1. doi: 10.1016/j.mechmat.2023.104601
Bai, Yongtao ; Li, Xiaolei ; Zhou, Xuhong et al. / Soil-expended seismic metamaterial with ultralow and wide bandgap. in: Mechanics of materials. 2023 ; Jahrgang 180.
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abstract = "The low-frequency wide-bandgap characteristics of the seismic metamaterial can suppress the propagation of vibrations and reduce the risk of extreme loadings such as earthquakes. The stringent requirement of lattice size extensively increawiths the cost of forming seismic metamaterial with general engineering materials. We design soil-expanded seismic metamaterial to reduce the scale restriction on artificial materials. Two types of soil-expanded lattice are created, and the bandgap characteristics for the lattice are obtained through the transfer matrix method. The propagation process for finite periodic lattice is simulated by the finite difference method in the time domain. It is found that the acceleration amplitudes in the wave propagation region are suppressed by 90% for the seismic metamaterial with rubber components. The response spectra further indicate that seismic metamaterials can reduce seismic risk in targeted areas.",
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author = "Yongtao Bai and Xiaolei Li and Xuhong Zhou and Peng Li and Michael Beer",
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AU - Li, Peng

AU - Beer, Michael

N1 - Funding Information: This study was partially supported by the National Key R&D Program of China under Grant No. 2022YFB2602700 , the National Natural Science Fund for Excellent Young Scientists Fund Program, Scientific Research Fund of the Institute of Engineering Mechanics, China Earthquake Administration ( 2020EEEVL0413 ), the Fundamental Research Funds for the Central Universities (Grant No. 2022CDJKYJH052 ), and the Support Plan for Returned Overseas Scholars of Chongqing ( cx2020022 ).

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AB - The low-frequency wide-bandgap characteristics of the seismic metamaterial can suppress the propagation of vibrations and reduce the risk of extreme loadings such as earthquakes. The stringent requirement of lattice size extensively increawiths the cost of forming seismic metamaterial with general engineering materials. We design soil-expanded seismic metamaterial to reduce the scale restriction on artificial materials. Two types of soil-expanded lattice are created, and the bandgap characteristics for the lattice are obtained through the transfer matrix method. The propagation process for finite periodic lattice is simulated by the finite difference method in the time domain. It is found that the acceleration amplitudes in the wave propagation region are suppressed by 90% for the seismic metamaterial with rubber components. The response spectra further indicate that seismic metamaterials can reduce seismic risk in targeted areas.

KW - Bandgap

KW - Periodic structures

KW - Seismic metamaterial

KW - Seismic prevention

KW - Soil-structure interaction

KW - Vibration attenuation

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