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Main Authors: Singh, H., Suryanarayanan, K., Virga, E. G.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.07502
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author Singh, H.
Suryanarayanan, K.
Virga, E. G.
author_facet Singh, H.
Suryanarayanan, K.
Virga, E. G.
contents We study spontaneous deformations of a ribbon made of nematic polymer networks and activated under the action of a mechanical load. We show that when such ribbons are activated appropriately, the deformations produced can pull back and perform work against the externally applied load. We perform two numerical experiments to demonstrate this effect: (1) the \emph{pulling} experiment, where the ribbon is pulled longitudinally by a point force, and (2) the \emph{bending} experiment, where the ribbon is bent out of plane by a terminally applied point force. We quantify the capacity of the ribbon to work against external loads, and compute its dependence on both the ribbon thickness and the imprinted nematic texture (that is, the distribution of the nematic directors across the ribbon's length). Finally, we compute the efficiency of the activation process. Building on the outcomes of our numerical explorations, we formulate two educated conjectures on how the activation efficiency can in general be improved by acting on both the applied load and the imprinted nematic texture.
format Preprint
id arxiv_https___arxiv_org_abs_2408_07502
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Work and Activation in a Nematic Polymer Network Ribbon
Singh, H.
Suryanarayanan, K.
Virga, E. G.
Soft Condensed Matter
We study spontaneous deformations of a ribbon made of nematic polymer networks and activated under the action of a mechanical load. We show that when such ribbons are activated appropriately, the deformations produced can pull back and perform work against the externally applied load. We perform two numerical experiments to demonstrate this effect: (1) the \emph{pulling} experiment, where the ribbon is pulled longitudinally by a point force, and (2) the \emph{bending} experiment, where the ribbon is bent out of plane by a terminally applied point force. We quantify the capacity of the ribbon to work against external loads, and compute its dependence on both the ribbon thickness and the imprinted nematic texture (that is, the distribution of the nematic directors across the ribbon's length). Finally, we compute the efficiency of the activation process. Building on the outcomes of our numerical explorations, we formulate two educated conjectures on how the activation efficiency can in general be improved by acting on both the applied load and the imprinted nematic texture.
title Work and Activation in a Nematic Polymer Network Ribbon
topic Soft Condensed Matter
url https://arxiv.org/abs/2408.07502