High-frequency parametric approximation of the Floquet-Bloch spectrum for anti-tetrachiral materials

@article{Bacigalupo2015HighfrequencyPA,
  title={High-frequency parametric approximation of the Floquet-Bloch spectrum for anti-tetrachiral materials},
  author={Andrea Bacigalupo and Marco Lepidi},
  journal={arXiv: Materials Science},
  year={2015}
}
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23 Citations
Background Citations
8
Methods Citations
4

23 Citations

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Citation Type

Passive control of wave propagation in periodic anti-tetrachiral meta-materials
Periodic anti-tetrachiral materials are strongly characterized by a marked auxeticity, the unusual and fascinating mechanical property mathematically expressed by negative values of the Poisson’s
Asymptotic approximation of the band structure for tetrachiral metamaterials
Multi-parametric sensitivity analysis of the band structure for tetrachiral inertial metamaterials
PASSIVE CONTROL OFWAVE PROPAGATION IN PERIODIC ANTI-TETRACHIRALMETA-MATERIALS
Periodic anti-tetrachiral materials are strongly characterized by a marked auxeticity, the unusual and fascinating mechanical property mathematically expressed by negative values of the Poisson’s
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Workshop of the IRP Coss&Vita Advances in ELAstoDYNamics, NonLinear Mechanics and Stability of architected materials and structures
Architected metamaterials yielding superior dynamic performances can be conceived by realizing local mechanisms of inertia amplification in the periodic microstructure [1]. A periodic cellular
Optimal design of auxetic hexachiral metamaterials with local resonators
A parametric beam lattice model is formulated to analyse the propagation properties of elastic in-plane waves in an auxetic material based on a hexachiral topology of the periodic cell, equipped with
Parametric design of the band structure for lattice materials
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References

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