Elasto-static micropolar behavior of a chiral auxetic lattice

Auxetic materials expand when stretched, and shrink when compressed. This is the result of a negative Poisson's ratio ν . Isotropic configurations with ν ≈ − 1 have been designed and are expected to provide increased shear stiffness G. This assumes that Young's modulus and ν can be enginee...

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Bibliographic Details
Published inJournal of the mechanics and physics of solids Vol. 60; no. 1; pp. 156 - 171
Main Authors Spadoni, A., Ruzzene, M.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 2012
Subjects
Auxetic
Cellular solids
Chiral lattice
Couple-stress elasticity
Deformation
Formability
Joining
Lattices
Mathematical models
Mindlin plates
Negative Poisson's ratio
Networks
Poissons ratio
Cellular solids
Auxetic
Couple-stress elasticity
Chiral lattice
Negative Poisson's ratio
Online AccessGet full text
ISSN0022-5096
1873-4782
DOI10.1016/j.jmps.2011.09.012

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Abstract Auxetic materials expand when stretched, and shrink when compressed. This is the result of a negative Poisson's ratio ν . Isotropic configurations with ν ≈ − 1 have been designed and are expected to provide increased shear stiffness G. This assumes that Young's modulus and ν can be engineered independently. In this article, a micropolar-continuum model is employed to describe the behavior of a representative auxetic structural network, the chiral lattice, in an attempt to remove the indeterminacy in its constitutive law resulting from ν = − 1 . While this indeterminacy is successfully removed, it is found that the shear modulus is an independent parameter and, for certain configurations, it is equal to that of the triangular lattice. This is remarkable as the chiral lattice is subject to bending deformation of its internal members, and thus is more compliant than the triangular lattice which is stretch dominated. The derived micropolar model also indicates that this unique lattice has the highest characteristic length scale l c of all known lattice topologies, as well as a negative first Lamé constant without violating bounds required for thermodynamic stability. We also find that hexagonal arrangements of deformable rings have a coupling number N=1. This is the first lattice reported in the literature for which couple-stress or Mindlin theory is necessary rather than being adopted a priori. ► The 2D auxetic materials have shear modulus bound by that of microstructures with axial deformations. ► Micropolar model is a continuous function of topology ranging from chiral to triangular lattices. ► Poisson's ratio shows boundary-layer behavior going from chiral to triangular configurations. ► The chiral lattice has highest characteristic length of all lattices reported in the literature. ► Hexagonal arrangements of deformable rings have coupling number N=1 requiring Mindlin theory.
AbstractList Auxetic materials expand when stretched, and shrink when compressed. This is the result of a negative Poisson's ratio ν . Isotropic configurations with ν ≈ − 1 have been designed and are expected to provide increased shear stiffness G. This assumes that Young's modulus and ν can be engineered independently. In this article, a micropolar-continuum model is employed to describe the behavior of a representative auxetic structural network, the chiral lattice, in an attempt to remove the indeterminacy in its constitutive law resulting from ν = − 1 . While this indeterminacy is successfully removed, it is found that the shear modulus is an independent parameter and, for certain configurations, it is equal to that of the triangular lattice. This is remarkable as the chiral lattice is subject to bending deformation of its internal members, and thus is more compliant than the triangular lattice which is stretch dominated. The derived micropolar model also indicates that this unique lattice has the highest characteristic length scale l c of all known lattice topologies, as well as a negative first Lamé constant without violating bounds required for thermodynamic stability. We also find that hexagonal arrangements of deformable rings have a coupling number N=1. This is the first lattice reported in the literature for which couple-stress or Mindlin theory is necessary rather than being adopted a priori. ► The 2D auxetic materials have shear modulus bound by that of microstructures with axial deformations. ► Micropolar model is a continuous function of topology ranging from chiral to triangular lattices. ► Poisson's ratio shows boundary-layer behavior going from chiral to triangular configurations. ► The chiral lattice has highest characteristic length of all lattices reported in the literature. ► Hexagonal arrangements of deformable rings have coupling number N=1 requiring Mindlin theory.
Auxetic materials expand when stretched, and shrink when compressed. This is the result of a negative Poisson's ratio I1/2. Isotropic configurations with I1/2 approximately -1 have been designed and are expected to provide increased shear stiffness G. This assumes that Young's modulus and I1/2 can be engineered independently. In this article, a micropolar-continuum model is employed to describe the behavior of a representative auxetic structural network, the chiral lattice, in an attempt to remove the indeterminacy in its constitutive law resulting from I1/2=-1. While this indeterminacy is successfully removed, it is found that the shear modulus is an independent parameter and, for certain configurations, it is equal to that of the triangular lattice. This is remarkable as the chiral lattice is subject to bending deformation of its internal members, and thus is more compliant than the triangular lattice which is stretch dominated. The derived micropolar model also indicates that this unique lattice has the highest characteristic length scale lc of all known lattice topologies, as well as a negative first Lame constant without violating bounds required for thermodynamic stability. We also find that hexagonal arrangements of deformable rings have a coupling number N=1. This is the first lattice reported in the literature for which couple-stress or Mindlin theory is necessary rather than being adopted a priori.
Author Spadoni, A.
Ruzzene, M.
Author_xml – sequence: 1
  givenname: A.
  surname: Spadoni
  fullname: Spadoni, A.
  email: alex.spadoni@epfl.ch
  organization: Institute of Mechanical Engineering, École Polytechnique Fédérale de Lausanne (EPFL), Laboratory of Wave Mechanics and Multi-Field Interactions, EPFL-STI-IGM-LOMI, ME B2 444, Station 9, 1015-CH Lausanne, Switzerland
– sequence: 2
  givenname: M.
  surname: Ruzzene
  fullname: Ruzzene, M.
  organization: School of Aerospace Engineering, Georgia Institute of Technology, USA
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Copyright 2011 Elsevier Ltd
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Issue 1
Keywords Cellular solids
Auxetic
Couple-stress elasticity
Chiral lattice
Negative Poisson's ratio
Language English
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Snippet Auxetic materials expand when stretched, and shrink when compressed. This is the result of a negative Poisson's ratio ν . Isotropic configurations with ν ≈ − 1...
Auxetic materials expand when stretched, and shrink when compressed. This is the result of a negative Poisson's ratio I1/2. Isotropic configurations with I1/2...
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SubjectTerms Auxetic
Cellular solids
Chiral lattice
Couple-stress elasticity
Deformation
Formability
Joining
Lattices
Mathematical models
Mindlin plates
Negative Poisson's ratio
Networks
Poissons ratio
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Title Elasto-static micropolar behavior of a chiral auxetic lattice
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