Systematic design of Cauchy symmetric structures through Bayesian optimization
Systematic design of Cauchy symmetric structures through Bayesian optimization
Using a new Bayesian Optimization algorithm to guide the design of mechanical metamaterials, we design nonhomogeneous 3D structures possessing the Cauchy symmetry, which dictates the relationship between continuum and atomic deformations. Recent efforts to merge optimization techniques with the design of mechanical metamaterials has resulted in a concentrated effort to tailor their elastic and post elastic properties. Even though these properties of either individual unit cells or homogenized continua can be simulated using multi-physics solvers and well established optimization schemes, they are often computationally expensive and require many design iterations, rendering the validation stage a significant obstacle in the design of new metamaterial designs. This study aims to provide a framework on how to utilize miniscule computational cost to control the elastic properties of metamaterials such that specific symmetries can be accomplished. Using the Cauchy symmetry as a design objective, we engineer structures through the strategic arrangement of 5 different unit cells in a 5×5×5 cubic symmetric microlattice structure. This lattice design, despite constituting a design space with 510 3D lattice configurations, can converge to an effective solution in only 69 function calls as a result of the efficiency of the new Bayesian optimization scheme. To validate the mechanical behavior of the design, the lattice structures were fabricated using multiphoton lithography and mechanically tested, revealing a close correlation between experiments and simulated results in the elastic regime. Ultimately, a similar methodology can be utilized to design metamaterials with other material properties, aspiring to control properties at different length scales, an endeavor that requires inordinate computation cost.
Cauchy symmetry, Helium ion microscopy, In-situ mechanical testing, Mechanical metamaterials, Optimization, Tailored elastic behavior
Sheikh, Haris Moazam
631e12be-9394-41fd-8e90-6ab416df0d76
Meier, Timon
9c5e7739-da5c-4ace-a3aa-51ea5cc2ddd6
Blankenship, Brian
2e592596-9bcd-4c33-8310-3f1d3dc090ad
Vangelatos, Zacharias
25af838c-8994-4ae3-9eea-146dde025bb9
Zhao, Naichen
2c470bb1-e1a4-442c-9baf-bcbe39cc261f
Marcus, Philip S.
71925db3-fc73-4df3-93ea-fecc0bd6412b
Grigoropoulos, Costas P.
917b5685-51cf-44f6-ae60-6c7ca5821af9
22 September 2022
Sheikh, Haris Moazam
631e12be-9394-41fd-8e90-6ab416df0d76
Meier, Timon
9c5e7739-da5c-4ace-a3aa-51ea5cc2ddd6
Blankenship, Brian
2e592596-9bcd-4c33-8310-3f1d3dc090ad
Vangelatos, Zacharias
25af838c-8994-4ae3-9eea-146dde025bb9
Zhao, Naichen
2c470bb1-e1a4-442c-9baf-bcbe39cc261f
Marcus, Philip S.
71925db3-fc73-4df3-93ea-fecc0bd6412b
Grigoropoulos, Costas P.
917b5685-51cf-44f6-ae60-6c7ca5821af9
Sheikh, Haris Moazam, Meier, Timon, Blankenship, Brian, Vangelatos, Zacharias, Zhao, Naichen, Marcus, Philip S. and Grigoropoulos, Costas P.
(2022)
Systematic design of Cauchy symmetric structures through Bayesian optimization.
International Journal of Mechanical Sciences, 236, [107741].
(doi:10.1016/j.ijmecsci.2022.107741).
Abstract
Using a new Bayesian Optimization algorithm to guide the design of mechanical metamaterials, we design nonhomogeneous 3D structures possessing the Cauchy symmetry, which dictates the relationship between continuum and atomic deformations. Recent efforts to merge optimization techniques with the design of mechanical metamaterials has resulted in a concentrated effort to tailor their elastic and post elastic properties. Even though these properties of either individual unit cells or homogenized continua can be simulated using multi-physics solvers and well established optimization schemes, they are often computationally expensive and require many design iterations, rendering the validation stage a significant obstacle in the design of new metamaterial designs. This study aims to provide a framework on how to utilize miniscule computational cost to control the elastic properties of metamaterials such that specific symmetries can be accomplished. Using the Cauchy symmetry as a design objective, we engineer structures through the strategic arrangement of 5 different unit cells in a 5×5×5 cubic symmetric microlattice structure. This lattice design, despite constituting a design space with 510 3D lattice configurations, can converge to an effective solution in only 69 function calls as a result of the efficiency of the new Bayesian optimization scheme. To validate the mechanical behavior of the design, the lattice structures were fabricated using multiphoton lithography and mechanically tested, revealing a close correlation between experiments and simulated results in the elastic regime. Ultimately, a similar methodology can be utilized to design metamaterials with other material properties, aspiring to control properties at different length scales, an endeavor that requires inordinate computation cost.
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More information
Accepted/In Press date: 8 September 2022
e-pub ahead of print date: 13 September 2022
Published date: 22 September 2022
Keywords:
Cauchy symmetry, Helium ion microscopy, In-situ mechanical testing, Mechanical metamaterials, Optimization, Tailored elastic behavior
Identifiers
Local EPrints ID: 493434
URI: http://eprints.soton.ac.uk/id/eprint/493434
ISSN: 0020-7403
PURE UUID: 469bd28c-d515-49c6-b513-f88cd792f19b
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Date deposited: 03 Sep 2024 16:33
Last modified: 04 Sep 2024 02:10
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Contributors
Author:
Haris Moazam Sheikh
Author:
Timon Meier
Author:
Brian Blankenship
Author:
Zacharias Vangelatos
Author:
Naichen Zhao
Author:
Philip S. Marcus
Author:
Costas P. Grigoropoulos
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