Programmable and reconfigurable hygro-thermo morphing materials with multifunctional shape transformation
Programmable and reconfigurable hygro-thermo morphing materials with multifunctional shape transformation
Humidity responsive materials are increasingly attracting significant interest for soft robotics and deployable structures. Their shape-changing behavior is based on differential hygroscopic characteristics of the single components of their microscopic architecture. Although existing moisture-induced materials achieve morphing in various humidity conditions, practical operational environments involve the presence of uncontrolled humidity regimes, which restrict those materials to reach broad ranges of shapes. Here we describe programmable and reconfigurable composite materials based on natural fibres and shape memory polymers that extend the current one-to-one relation between external humidity and final actuated shape. The heating of flexible polymer networks permits to program the architecture of the natural fibres flax reinforcements and their spatial distribution within the composite, when a moisture gradient is present. Once cooled, the programmed materials create new sets of different shapes, even when exposed to the same humidity conditions. These multifunctional biobased materials also show large stiffness (>13 GPa) that make them suitable for structural load-bearing applications. New multifunctional shape transformations capabilities of these bio-based hygro-thermo composites are demonstrated in a bio-robotic grasping hand and a bio-frame for electro-adhesive gripping. These examples show the full functionality, structural integrity, programmability and remarkable mechanical properties of our multifunctional hygromorph biocomposites.
Hygromorph, Programmable, Reconfigurable, Shape memory polymers
Li, Qinyu
f5c152e9-2773-4d5c-aabf-a21b09cee293
Sun, Rujie
e3dad16d-6c79-4972-8378-edca28a3babd
Le Duigou, Antoine
2057e4ba-c725-42a4-ab07-d4320b03d477
Guo, Jianglong
d30e32cc-f4fa-4668-99cd-2e16d0e3151a
Rossiter, Jonathan
64caa0df-19e0-40c8-ab69-7021de665c39
Liu, Liwu
2b5a69c9-297d-46d4-b005-0cae6062d1a1
Leng, Jinsong
540af013-0959-4a11-9014-a4b36f5b67fb
Scarpa, Fabrizio
684472c3-1a28-478a-a388-5fd896986c1d
11 February 2022
Li, Qinyu
f5c152e9-2773-4d5c-aabf-a21b09cee293
Sun, Rujie
e3dad16d-6c79-4972-8378-edca28a3babd
Le Duigou, Antoine
2057e4ba-c725-42a4-ab07-d4320b03d477
Guo, Jianglong
d30e32cc-f4fa-4668-99cd-2e16d0e3151a
Rossiter, Jonathan
64caa0df-19e0-40c8-ab69-7021de665c39
Liu, Liwu
2b5a69c9-297d-46d4-b005-0cae6062d1a1
Leng, Jinsong
540af013-0959-4a11-9014-a4b36f5b67fb
Scarpa, Fabrizio
684472c3-1a28-478a-a388-5fd896986c1d
Li, Qinyu, Sun, Rujie, Le Duigou, Antoine, Guo, Jianglong, Rossiter, Jonathan, Liu, Liwu, Leng, Jinsong and Scarpa, Fabrizio
(2022)
Programmable and reconfigurable hygro-thermo morphing materials with multifunctional shape transformation.
Applied Materials Today, 27, [101414].
(doi:10.1016/j.apmt.2022.101414).
Abstract
Humidity responsive materials are increasingly attracting significant interest for soft robotics and deployable structures. Their shape-changing behavior is based on differential hygroscopic characteristics of the single components of their microscopic architecture. Although existing moisture-induced materials achieve morphing in various humidity conditions, practical operational environments involve the presence of uncontrolled humidity regimes, which restrict those materials to reach broad ranges of shapes. Here we describe programmable and reconfigurable composite materials based on natural fibres and shape memory polymers that extend the current one-to-one relation between external humidity and final actuated shape. The heating of flexible polymer networks permits to program the architecture of the natural fibres flax reinforcements and their spatial distribution within the composite, when a moisture gradient is present. Once cooled, the programmed materials create new sets of different shapes, even when exposed to the same humidity conditions. These multifunctional biobased materials also show large stiffness (>13 GPa) that make them suitable for structural load-bearing applications. New multifunctional shape transformations capabilities of these bio-based hygro-thermo composites are demonstrated in a bio-robotic grasping hand and a bio-frame for electro-adhesive gripping. These examples show the full functionality, structural integrity, programmability and remarkable mechanical properties of our multifunctional hygromorph biocomposites.
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Accepted/In Press date: 2 February 2022
Published date: 11 February 2022
Keywords:
Hygromorph, Programmable, Reconfigurable, Shape memory polymers
Identifiers
Local EPrints ID: 486838
URI: http://eprints.soton.ac.uk/id/eprint/486838
ISSN: 2352-9407
PURE UUID: e3da5f84-af02-40e0-accb-26d9c37cbcf7
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Date deposited: 06 Feb 2024 17:53
Last modified: 17 Mar 2024 07:24
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Contributors
Author:
Qinyu Li
Author:
Rujie Sun
Author:
Antoine Le Duigou
Author:
Jianglong Guo
Author:
Jonathan Rossiter
Author:
Liwu Liu
Author:
Jinsong Leng
Author:
Fabrizio Scarpa
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