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Voltage-dependent modulation of elastic moduli in lattice metamaterials: emergence of a programmable state-transition capability

Voltage-dependent modulation of elastic moduli in lattice metamaterials: emergence of a programmable state-transition capability
Voltage-dependent modulation of elastic moduli in lattice metamaterials: emergence of a programmable state-transition capability

Two-dimensional lattices are ideal candidate for developing artificially engineered materials and structures across different length-scales, leading to unprecedented multi-functional mechanical properties which can not be achieved in naturally occurring materials and systems. Characterization of effective elastic properties of these lattices is essential for their adoption as structural elements of various devices and systems. An enormous amount of research has been conducted on different geometry of lattices to identify and characterize various parameters which affect the elastic properties. However, till date we can not control the elastic properties actively for a lattice microstructure, meaning that the elastic properties of such lattices are not truly programmable. All the parameters that control the effective elastic properties are passive in nature. After manufacturing the lattice structure with a certain set of geometric or material-based parameters, there is no room to modulate the properties further. In this article, we propose a hybrid lattice micro-structure by integrating piezo-electric materials with the members of the lattice for active voltage-dependent modulation of elastic properties. A bottom-up multi-physics based analytical framework leading to closed-form formulae is derived for hexagonal lattices to demonstrate the concept of active lattices. It is noticed that the Young's moduli are voltage-dependent, while the shear modulus and the Poisson's ratios are not functions of the applied voltage. Thus, the compound mechanics of deformation induced by external mechanical stresses and electric field lead to an active control over the Young's moduli as a function of voltage. Interestingly, it turns out that a programmable state-transition of the Young's moduli from positive to negative values with a wide range can be achieved in such hybrid lattices. The physics-based analytical framework for active modulation of voltage-dependent elastic properties on the basis of operational demands provide the necessary physical insights and confidence for potential practical exploitation of the proposed concept in various futuristic multi-functional structural systems and devices across different length-scales.

Active honeycombs, Elastic properties of lattices, Hybrid piezoelectric honeycomb, Multi-physical lattice microstructures, Negative Young's modulus
0020-7683
31-48
Singh, A.
682948e0-942b-47a8-8b12-20a3e7c9a428
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Adhikari, S.
82960baf-916c-496e-aa85-fc7de09a1626
Bhattacharya, B.
c3f6b49e-3efa-415a-88b1-ae4f108ad70d
Singh, A.
682948e0-942b-47a8-8b12-20a3e7c9a428
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Adhikari, S.
82960baf-916c-496e-aa85-fc7de09a1626
Bhattacharya, B.
c3f6b49e-3efa-415a-88b1-ae4f108ad70d

Singh, A., Mukhopadhyay, T., Adhikari, S. and Bhattacharya, B. (2021) Voltage-dependent modulation of elastic moduli in lattice metamaterials: emergence of a programmable state-transition capability. International Journal of Solids and Structures, 208-209, 31-48. (doi:10.1016/j.ijsolstr.2020.10.009).

Record type: Article

Abstract

Two-dimensional lattices are ideal candidate for developing artificially engineered materials and structures across different length-scales, leading to unprecedented multi-functional mechanical properties which can not be achieved in naturally occurring materials and systems. Characterization of effective elastic properties of these lattices is essential for their adoption as structural elements of various devices and systems. An enormous amount of research has been conducted on different geometry of lattices to identify and characterize various parameters which affect the elastic properties. However, till date we can not control the elastic properties actively for a lattice microstructure, meaning that the elastic properties of such lattices are not truly programmable. All the parameters that control the effective elastic properties are passive in nature. After manufacturing the lattice structure with a certain set of geometric or material-based parameters, there is no room to modulate the properties further. In this article, we propose a hybrid lattice micro-structure by integrating piezo-electric materials with the members of the lattice for active voltage-dependent modulation of elastic properties. A bottom-up multi-physics based analytical framework leading to closed-form formulae is derived for hexagonal lattices to demonstrate the concept of active lattices. It is noticed that the Young's moduli are voltage-dependent, while the shear modulus and the Poisson's ratios are not functions of the applied voltage. Thus, the compound mechanics of deformation induced by external mechanical stresses and electric field lead to an active control over the Young's moduli as a function of voltage. Interestingly, it turns out that a programmable state-transition of the Young's moduli from positive to negative values with a wide range can be achieved in such hybrid lattices. The physics-based analytical framework for active modulation of voltage-dependent elastic properties on the basis of operational demands provide the necessary physical insights and confidence for potential practical exploitation of the proposed concept in various futuristic multi-functional structural systems and devices across different length-scales.

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More information

Accepted/In Press date: 9 October 2020
Published date: 1 January 2021
Additional Information: Funding Information: The authors acknowledge the financial support from Visvesvaraya PhD scheme, Media Lab Asia, Ministry of Electronics and Information Technology, Government of India, through a scholarship (MLA/ME/2015210P) and SPARC project (MHRD/ME/2018544). TM acknowledges the initiation grant received from IIT Kanpur. SA acknowledges the support of UK-India Education and Research Initiative through Grant No. UKIERI/P1212. Publisher Copyright: © 2020 Elsevier Ltd
Keywords: Active honeycombs, Elastic properties of lattices, Hybrid piezoelectric honeycomb, Multi-physical lattice microstructures, Negative Young's modulus

Identifiers

Local EPrints ID: 483898
URI: http://eprints.soton.ac.uk/id/eprint/483898
DOI: doi:10.1016/j.ijsolstr.2020.10.009
ISSN: 0020-7683
PURE UUID: a049bbb4-48e8-4228-89bb-939f2231934e
ORCID for T. Mukhopadhyay: ORCID iD orcid.org/0000-0002-0778-6515

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Date deposited: 07 Nov 2023 18:07
Last modified: 18 Mar 2024 04:10

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Contributors

Author: A. Singh
Author: T. Mukhopadhyay ORCID iD
Author: S. Adhikari
Author: B. Bhattacharya

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