Extreme specific stiffness through interactive cellular networks in bi-level micro-topology architected metamaterials
Extreme specific stiffness through interactive cellular networks in bi-level micro-topology architected metamaterials
Architected lattice materials, realized through artificial micro-structuring, have drawn tremendous attention lately due to their enhanced mechanical performances in multifunctional applications. However, the research area on the design of artificial microstructures for the modulation of mechanical properties is increasingly becoming saturated due to extensive investigations considering different possibilities of lattice geometry and beam-like network design. Thus, there exists a strong rationale for innovative design at a more elementary level. It can enhance and grow the microstructural space laterally for exploiting the potential of geometries and patterns in multiple length scales, and the mutual interactions thereof. A bi-level design is proposed, where besides having the architected cellular networks at an upper scale, the constituting beam-like members at a lower scale are further topology-engineered for most optimum material utilization. The coupled interaction of beam-level and lattice-level architectures can enhance the specific elastic properties to an extreme extent (up to ≈25 and 20 times, depending on normal and shear modes, respectively), leading to ultra-lightweight multifunctional materials for critical applications under static and dynamic environments.
auxetic metamaterials, bi-level topology-architected lattices, extreme specific stiffness, lattice materials, tunable elastic moduli
Kundu, Diptiman
fa5a739b-ebf9-488f-91bf-d84a1fe62519
Ghuku, Sushanta
b27d55ee-089d-4142-b5b7-4a065a977057
Naskar, Susmita
5f787953-b062-4774-a28b-473bd19254b1
Mukhopadhyay, Tanmoy
2ae18ab0-7477-40ac-ae22-76face7be475
15 December 2022
Kundu, Diptiman
fa5a739b-ebf9-488f-91bf-d84a1fe62519
Ghuku, Sushanta
b27d55ee-089d-4142-b5b7-4a065a977057
Naskar, Susmita
5f787953-b062-4774-a28b-473bd19254b1
Mukhopadhyay, Tanmoy
2ae18ab0-7477-40ac-ae22-76face7be475
Kundu, Diptiman, Ghuku, Sushanta, Naskar, Susmita and Mukhopadhyay, Tanmoy
(2022)
Extreme specific stiffness through interactive cellular networks in bi-level micro-topology architected metamaterials.
Advanced Engineering Materials.
(doi:10.1002/adem.202201407).
Abstract
Architected lattice materials, realized through artificial micro-structuring, have drawn tremendous attention lately due to their enhanced mechanical performances in multifunctional applications. However, the research area on the design of artificial microstructures for the modulation of mechanical properties is increasingly becoming saturated due to extensive investigations considering different possibilities of lattice geometry and beam-like network design. Thus, there exists a strong rationale for innovative design at a more elementary level. It can enhance and grow the microstructural space laterally for exploiting the potential of geometries and patterns in multiple length scales, and the mutual interactions thereof. A bi-level design is proposed, where besides having the architected cellular networks at an upper scale, the constituting beam-like members at a lower scale are further topology-engineered for most optimum material utilization. The coupled interaction of beam-level and lattice-level architectures can enhance the specific elastic properties to an extreme extent (up to ≈25 and 20 times, depending on normal and shear modes, respectively), leading to ultra-lightweight multifunctional materials for critical applications under static and dynamic environments.
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Adv Eng Mater - 2022 - Kundu - Extreme Specific Stiffness Through Interactive Cellular Networks in Bi‐Level Micro‐Topology
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Accepted/In Press date: 28 November 2022
e-pub ahead of print date: 28 November 2022
Published date: 15 December 2022
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Funding Information:
D.K., S.G., T.M. and S.N. contributed equally to this work, as written in the originally supplied version. D.K. acknowledges the financial support from the Ministry of Education, India, through a scholarship. S.N. acknowledges the Initiation grant received from the University of Southampton. T.M. would like to acknowledge the Initiation grant received from IIT Kanpur during the period of this research work.
Publisher Copyright:
© 2022 The Authors. Advanced Engineering Materials published by Wiley-VCH GmbH.
Keywords:
auxetic metamaterials, bi-level topology-architected lattices, extreme specific stiffness, lattice materials, tunable elastic moduli
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Local EPrints ID: 472954
URI: http://eprints.soton.ac.uk/id/eprint/472954
ISSN: 1438-1656
PURE UUID: ee5fe73b-8e3d-48d7-9f76-68f052d993ee
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Date deposited: 06 Jan 2023 13:02
Last modified: 06 Jun 2024 02:16
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Author:
Diptiman Kundu
Author:
Sushanta Ghuku
Author:
Tanmoy Mukhopadhyay
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