Anisotropy tailoring in geometrically isotropic multi-material lattices
Anisotropy tailoring in geometrically isotropic multi-material lattices
This article proposes the concept of anisotropy tailoring in multi-material lattices based on a mechanics-based bottom-up framework. It is widely known that isotropy in a mono-material lattice can be obtained when the microstructure has an isotropic geometry. For example, regular hexagonal lattices with a unit cell comprised of six equal members and equal internal angle of each, show isotropy in the elastic properties. Such limited microstructural configuration space for having isotropy severely restricts the scope of many multi-functional applications such as space filling in 3D printing. We first demonstrate that there are multiple structural geometries in mono-material lattices that could lead to isotropy. It is shown that the configuration space for isotropy can be expanded by multiple folds when more than one intrinsic material is introduced in the unit cell of a lattice. We explicitly demonstrate different degrees of anisotropy in regular geometrically isotropic lattices by introducing the multi-material architecture. The contours of achieving minimum anisotropy, maximum anisotropy and a fixed value of anisotropy are presented in the design space consisting of geometric and multi-material parameters. Proposition of such multi-material microstructures could essentially expand the multi-functional design scope significantly, offering a higher degree of flexibility to the designer in terms of choosing (or identifying) the most suitable microstructural geometry. An explicit theoretical characterization of the contours of anisotropy along with physical insights underpinning the configuration space of multi-material and geometric parameters will accelerate the process of its potential exploitation in various engineered multi-functional materials and structural systems across different length-scales with the demand of any specific degree of anisotropy but limitation in the micro-structural geometry.
Mukhopadhyay, T.
f64d974a-f8c4-4a3a-85db-4136bad75811
Naskar, S.
5f787953-b062-4774-a28b-473bd19254b1
Adhikari, S.
82960baf-916c-496e-aa85-fc7de09a1626
1 October 2020
Mukhopadhyay, T.
f64d974a-f8c4-4a3a-85db-4136bad75811
Naskar, S.
5f787953-b062-4774-a28b-473bd19254b1
Adhikari, S.
82960baf-916c-496e-aa85-fc7de09a1626
Mukhopadhyay, T., Naskar, S. and Adhikari, S.
(2020)
Anisotropy tailoring in geometrically isotropic multi-material lattices.
Extreme Mechanics Letters, 40, [100934].
(doi:10.1016/j.eml.2020.100934).
Abstract
This article proposes the concept of anisotropy tailoring in multi-material lattices based on a mechanics-based bottom-up framework. It is widely known that isotropy in a mono-material lattice can be obtained when the microstructure has an isotropic geometry. For example, regular hexagonal lattices with a unit cell comprised of six equal members and equal internal angle of each, show isotropy in the elastic properties. Such limited microstructural configuration space for having isotropy severely restricts the scope of many multi-functional applications such as space filling in 3D printing. We first demonstrate that there are multiple structural geometries in mono-material lattices that could lead to isotropy. It is shown that the configuration space for isotropy can be expanded by multiple folds when more than one intrinsic material is introduced in the unit cell of a lattice. We explicitly demonstrate different degrees of anisotropy in regular geometrically isotropic lattices by introducing the multi-material architecture. The contours of achieving minimum anisotropy, maximum anisotropy and a fixed value of anisotropy are presented in the design space consisting of geometric and multi-material parameters. Proposition of such multi-material microstructures could essentially expand the multi-functional design scope significantly, offering a higher degree of flexibility to the designer in terms of choosing (or identifying) the most suitable microstructural geometry. An explicit theoretical characterization of the contours of anisotropy along with physical insights underpinning the configuration space of multi-material and geometric parameters will accelerate the process of its potential exploitation in various engineered multi-functional materials and structural systems across different length-scales with the demand of any specific degree of anisotropy but limitation in the micro-structural geometry.
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Accepted/In Press date: 11 August 2020
e-pub ahead of print date: 9 September 2020
Published date: 1 October 2020
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Local EPrints ID: 451963
URI: http://eprints.soton.ac.uk/id/eprint/451963
PURE UUID: 210887d8-3450-455d-8739-b14b378eb714
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Date deposited: 04 Nov 2021 17:34
Last modified: 17 Mar 2024 04:07
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Author:
T. Mukhopadhyay
Author:
S. Adhikari
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