Multi-scale non-affine mechanics of electro-magneto-active elastomers: Taut domain exploitable convolution of polymer chain crosslinks, entanglements and finite extensibility
Multi-scale non-affine mechanics of electro-magneto-active elastomers: Taut domain exploitable convolution of polymer chain crosslinks, entanglements and finite extensibility
Actuation devices fabricated using smart polymers often exhibit wrinkling and pull-in instability when they are subjected to external stimulation. These instabilities can disrupt the intended functionality of the actuation devices and hinder their reliability. The underlying reason for these instabilities is the complicated architecture of the polymer network, which results in a complex and chaotic arrangement of crosslinks and entanglements in smart elastomer membranes. This convoluted structure significantly influences the mechanical behavior of the polymers when external forces are applied. To better understand and characterize these instability phenomena, the present study develops a physics-based non-affine material model incorporating the effects of critical factors like polymer chain crosslinks, entanglements, and finite extensibility. By considering the intricate interplay among these factors, the model provides fundamental insights into the mechanisms behind the instability phenomena in smart polymers. Subsequently, the study explores the relationship between the applied electromagnetic field and the taut domains. The findings reveal that the size of the taut domains can be effectively altered by manipulating the levels of polymer chain crosslinks, entanglements, and finite extensibility. It is observed that, for a given level of applied electromagnetic field, increasing the entanglement and crosslink parameter leads to a larger taut domain. Conversely, an increase in the finite extensibility of the polymer chain diminishes the taut domain under the same level of electromagnetic loading. These understandings open up new avenues for optimizing actuation devices by adjusting the intricate properties of polymer chains to enhance stability and performance by unlocking the full multi-physical potential of smart elastomers.
Crosslinks, Entanglements, Finite extensibility, Non-affine model, Smart electromagnetic thin membrane, Taut domains
Khurana, Aman
310738d7-0cdf-4568-8e8e-bb0aad270c7b
Naskar, Susmita
5f787953-b062-4774-a28b-473bd19254b1
Joglekar, M.M.
5c341547-d8b5-46eb-9653-f7be46d89379
Mukhopadhyay, Tanmoy
2ae18ab0-7477-40ac-ae22-76face7be475
1 December 2025
Khurana, Aman
310738d7-0cdf-4568-8e8e-bb0aad270c7b
Naskar, Susmita
5f787953-b062-4774-a28b-473bd19254b1
Joglekar, M.M.
5c341547-d8b5-46eb-9653-f7be46d89379
Mukhopadhyay, Tanmoy
2ae18ab0-7477-40ac-ae22-76face7be475
Khurana, Aman, Naskar, Susmita, Joglekar, M.M. and Mukhopadhyay, Tanmoy
(2025)
Multi-scale non-affine mechanics of electro-magneto-active elastomers: Taut domain exploitable convolution of polymer chain crosslinks, entanglements and finite extensibility.
International Journal of Engineering Science, 217, [104378].
(doi:10.1016/j.ijengsci.2025.104378).
Abstract
Actuation devices fabricated using smart polymers often exhibit wrinkling and pull-in instability when they are subjected to external stimulation. These instabilities can disrupt the intended functionality of the actuation devices and hinder their reliability. The underlying reason for these instabilities is the complicated architecture of the polymer network, which results in a complex and chaotic arrangement of crosslinks and entanglements in smart elastomer membranes. This convoluted structure significantly influences the mechanical behavior of the polymers when external forces are applied. To better understand and characterize these instability phenomena, the present study develops a physics-based non-affine material model incorporating the effects of critical factors like polymer chain crosslinks, entanglements, and finite extensibility. By considering the intricate interplay among these factors, the model provides fundamental insights into the mechanisms behind the instability phenomena in smart polymers. Subsequently, the study explores the relationship between the applied electromagnetic field and the taut domains. The findings reveal that the size of the taut domains can be effectively altered by manipulating the levels of polymer chain crosslinks, entanglements, and finite extensibility. It is observed that, for a given level of applied electromagnetic field, increasing the entanglement and crosslink parameter leads to a larger taut domain. Conversely, an increase in the finite extensibility of the polymer chain diminishes the taut domain under the same level of electromagnetic loading. These understandings open up new avenues for optimizing actuation devices by adjusting the intricate properties of polymer chains to enhance stability and performance by unlocking the full multi-physical potential of smart elastomers.
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Accepted/In Press date: 24 August 2025
Published date: 1 December 2025
Keywords:
Crosslinks, Entanglements, Finite extensibility, Non-affine model, Smart electromagnetic thin membrane, Taut domains
Identifiers
Local EPrints ID: 506461
URI: http://eprints.soton.ac.uk/id/eprint/506461
ISSN: 0020-7225
PURE UUID: 6455f122-8f94-4b29-bc0f-0e0cbd66a068
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Date deposited: 07 Nov 2025 17:47
Last modified: 02 Dec 2025 03:01
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Author:
Aman Khurana
Author:
M.M. Joglekar
Author:
Tanmoy Mukhopadhyay
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