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Hydrated behavior of multilayer polyelectrolyte-nanoclay coatings on porous materials and demonstration of shape memory effect

Hydrated behavior of multilayer polyelectrolyte-nanoclay coatings on porous materials and demonstration of shape memory effect
Hydrated behavior of multilayer polyelectrolyte-nanoclay coatings on porous materials and demonstration of shape memory effect
Layer-by-layer (LbL) assembly is a powerful technique for fabricating nanocomposite thin-film coatings with a diverse range of constituents, properties, and functionalities. Templated deposition of these coatings has enabled the translation of mechanical properties from the microscale of thin-films to the macro-scale of nanocomposite-coated porous materials and has been used to tailor the elastic modulus and porosity of coated open-cell foams for potential applications including lightweight structures and engineered tissue scaffolds. However, the presence of moisture in these application environments is expected to affect the physico-mechanical behavior of the nanocomposite coating. In this work, open-cell foams coated with nanocomposites consisting of poly(ethyleneimine), poly(acrylic acid), and Na+-montmorillonite were characterised under high relative humidity and upon complete submersion in water. The nanocomposite coating imparted a substantial increase in compressive elastic modulus when tested under ambient conditions, from 0.08 ± 0.00 MPa to 4.90 ± 0.46 MPa, but had little to no mechanical effect when hydrated, and upon drying the mechanical properties of coated foams recovered to pre-hydrated levels. Chemical crosslinking of amine groups within the polymers resulted in the retention of significant compressive elastic modulus of 2.91 ± 0.49 MPa when hydrated. Initial trials showed that un-crosslinked coated foams exhibit a hydration induced shape memory effect that could be used to enable the actuation or expansion of a previously passive open-cell foam.
Crosslinking, Hydration, Layer-by-layer assembly, Shape memory foams
0257-8972
Acheson, Jonathan
b4781eeb-9e88-4337-99af-74a2083d58ad
McFerran, Aoife
0d21918d-65d2-4ad1-bbc2-36adaaded7bd
Xu, Dichu
e91ddedf-af9a-4f0c-834b-3e538c2e166b
Ziminska, Monika
a53248bb-9825-4aa4-a9ea-2701a7f618f1
Goel, Saurav
5561ff43-641b-4db7-b6b0-45200f186bbd
Lennon, Alexander B.
59872108-8d61-44cd-ab46-1509a222c1fd
Dunne, Nicholas
d807aea4-6553-47da-a06d-dfb0d4bbe690
Hamilton, Andrew
9088cf01-8d7f-45f0-af56-b4784227447c
Acheson, Jonathan
b4781eeb-9e88-4337-99af-74a2083d58ad
McFerran, Aoife
0d21918d-65d2-4ad1-bbc2-36adaaded7bd
Xu, Dichu
e91ddedf-af9a-4f0c-834b-3e538c2e166b
Ziminska, Monika
a53248bb-9825-4aa4-a9ea-2701a7f618f1
Goel, Saurav
5561ff43-641b-4db7-b6b0-45200f186bbd
Lennon, Alexander B.
59872108-8d61-44cd-ab46-1509a222c1fd
Dunne, Nicholas
d807aea4-6553-47da-a06d-dfb0d4bbe690
Hamilton, Andrew
9088cf01-8d7f-45f0-af56-b4784227447c

Acheson, Jonathan, McFerran, Aoife, Xu, Dichu, Ziminska, Monika, Goel, Saurav, Lennon, Alexander B., Dunne, Nicholas and Hamilton, Andrew (2023) Hydrated behavior of multilayer polyelectrolyte-nanoclay coatings on porous materials and demonstration of shape memory effect. Surface and Coatings Technology, 458, [129335]. (doi:10.1016/j.surfcoat.2023.129335).

Record type: Article

Abstract

Layer-by-layer (LbL) assembly is a powerful technique for fabricating nanocomposite thin-film coatings with a diverse range of constituents, properties, and functionalities. Templated deposition of these coatings has enabled the translation of mechanical properties from the microscale of thin-films to the macro-scale of nanocomposite-coated porous materials and has been used to tailor the elastic modulus and porosity of coated open-cell foams for potential applications including lightweight structures and engineered tissue scaffolds. However, the presence of moisture in these application environments is expected to affect the physico-mechanical behavior of the nanocomposite coating. In this work, open-cell foams coated with nanocomposites consisting of poly(ethyleneimine), poly(acrylic acid), and Na+-montmorillonite were characterised under high relative humidity and upon complete submersion in water. The nanocomposite coating imparted a substantial increase in compressive elastic modulus when tested under ambient conditions, from 0.08 ± 0.00 MPa to 4.90 ± 0.46 MPa, but had little to no mechanical effect when hydrated, and upon drying the mechanical properties of coated foams recovered to pre-hydrated levels. Chemical crosslinking of amine groups within the polymers resulted in the retention of significant compressive elastic modulus of 2.91 ± 0.49 MPa when hydrated. Initial trials showed that un-crosslinked coated foams exhibit a hydration induced shape memory effect that could be used to enable the actuation or expansion of a previously passive open-cell foam.

Text
Hydration actuation crosslinking LbL QLs 2022 FINAL - Accepted Manuscript
Restricted to Repository staff only until 6 February 2025.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
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Accepted/In Press date: 6 February 2023
e-pub ahead of print date: 14 February 2023
Published date: 15 April 2023
Additional Information: Funding Information: The authors would like to thank Blagden Specialty Chemicals and BYK additives for their kind provision of a sample of Cloisite Na + nanoclay powder. We also acknowledge Dr. Paul Baine from Queen's University Belfast, School of Electronics, Electrical Engineering and Computer Science for kindly providing access to and assistance with stylus profilometry. This work was funded by a PhD studentship from the Department for the Economy in Northern Ireland . Funding Information: The authors would like to thank Blagden Specialty Chemicals and BYK additives for their kind provision of a sample of Cloisite Na+ nanoclay powder. We also acknowledge Dr. Paul Baine from Queen's University Belfast, School of Electronics, Electrical Engineering and Computer Science for kindly providing access to and assistance with stylus profilometry. This work was funded by a PhD studentship from the Department for the Economy in Northern Ireland. Publisher Copyright: © 2023
Keywords: Crosslinking, Hydration, Layer-by-layer assembly, Shape memory foams
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Identifiers

Local EPrints ID: 476590
URI: http://eprints.soton.ac.uk/id/eprint/476590
DOI: doi:10.1016/j.surfcoat.2023.129335
ISSN: 0257-8972
PURE UUID: 92f48db6-5bf2-41d0-a0c8-ee1db41ecf05
ORCID for Andrew Hamilton: ORCID iD orcid.org/0000-0003-4627-849X

Catalogue record

Date deposited: 09 May 2023 16:50
Last modified: 06 Jun 2024 01:59

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Contributors

Author: Jonathan Acheson
Author: Aoife McFerran
Author: Dichu Xu
Author: Monika Ziminska
Author: Saurav Goel
Author: Alexander B. Lennon
Author: Nicholas Dunne
Author: Andrew Hamilton ORCID iD

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