Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte
Fibrillar hydrogels are remarkably stiff, low-density networks that can hold vast amounts of water. These hydrogels can easily be made anisotropic by orienting the fibrils using different methods. Unlike the detailed and established descriptions of polymer gels, there is no coherent theoretical fram...
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sg-ntu-dr.10356-1706242023-09-25T00:45:05Z Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte Östmans, Rebecca Cortes Ruiz, Maria F. Rostami, Jowan Sellman, Farhiya Alex Wågberg, Lars Lindström, Stefan B. Benselfelt, Tobias School of Materials Science and Engineering Engineering::Materials Cellulose Nanofibrils Adsorption Fibrillar hydrogels are remarkably stiff, low-density networks that can hold vast amounts of water. These hydrogels can easily be made anisotropic by orienting the fibrils using different methods. Unlike the detailed and established descriptions of polymer gels, there is no coherent theoretical framework describing the elastoplastic behavior of fibrillar gels, especially concerning anisotropy. In this work, the swelling pressures of anisotropic fibrillar hydrogels made from cellulose nanofibrils were measured in the direction perpendicular to the fibril alignment. This experimental data was used to develop a model comprising three mechanical elements representing the network and the osmotic pressure due to non-ionic and ionic surface groups on the fibrils. At low solidity, the stiffness of the hydrogels was dominated by the ionic swelling pressure governed by the osmotic ingress of water. Fibrils with different functionality show the influence of aspect ratio, chemical functionality, and the remaining amount of hemicelluloses. This general model describes physically crosslinked hydrogels comprising fibrils with high flexural rigidity - that is, with a persistence length larger than the mesh size. The experimental technique is a framework to study and understand the importance of fibrillar networks for the evolution of multicellular organisms, like plants, and the influence of different components in plant cell walls. The Knut and Alice Wallenberg Foundation are acknowledged for funding through the Wallenberg Wood Science Center (WWSC) and an individual fellowship for Tobias Benselfelt (KAW 2019.0564). Stefan B. Lindstroem works within the Neopulp research profile financed by the Knowledge Foundation, and also thanks SCA for financial support. 2023-09-25T00:45:05Z 2023-09-25T00:45:05Z 2023 Journal Article Östmans, R., Cortes Ruiz, M. F., Rostami, J., Sellman, F. A., Wågberg, L., Lindström, S. B. & Benselfelt, T. (2023). Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte. Soft Matter, 19(15), 2792-2800. https://dx.doi.org/10.1039/D2SM01571D 1744-683X https://hdl.handle.net/10356/170624 10.1039/D2SM01571D 15 19 2792 2800 en Soft Matter © 2023 The Royal Society of Chemistry. All rights reserved. |
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Engineering::Materials Cellulose Nanofibrils Adsorption Östmans, Rebecca Cortes Ruiz, Maria F. Rostami, Jowan Sellman, Farhiya Alex Wågberg, Lars Lindström, Stefan B. Benselfelt, Tobias Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte |
| description |
Fibrillar hydrogels are remarkably stiff, low-density networks that can hold vast amounts of water. These hydrogels can easily be made anisotropic by orienting the fibrils using different methods. Unlike the detailed and established descriptions of polymer gels, there is no coherent theoretical framework describing the elastoplastic behavior of fibrillar gels, especially concerning anisotropy. In this work, the swelling pressures of anisotropic fibrillar hydrogels made from cellulose nanofibrils were measured in the direction perpendicular to the fibril alignment. This experimental data was used to develop a model comprising three mechanical elements representing the network and the osmotic pressure due to non-ionic and ionic surface groups on the fibrils. At low solidity, the stiffness of the hydrogels was dominated by the ionic swelling pressure governed by the osmotic ingress of water. Fibrils with different functionality show the influence of aspect ratio, chemical functionality, and the remaining amount of hemicelluloses. This general model describes physically crosslinked hydrogels comprising fibrils with high flexural rigidity - that is, with a persistence length larger than the mesh size. The experimental technique is a framework to study and understand the importance of fibrillar networks for the evolution of multicellular organisms, like plants, and the influence of different components in plant cell walls. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Östmans, Rebecca Cortes Ruiz, Maria F. Rostami, Jowan Sellman, Farhiya Alex Wågberg, Lars Lindström, Stefan B. Benselfelt, Tobias |
| format |
Article |
| author |
Östmans, Rebecca Cortes Ruiz, Maria F. Rostami, Jowan Sellman, Farhiya Alex Wågberg, Lars Lindström, Stefan B. Benselfelt, Tobias |
| author_sort |
Östmans, Rebecca |
| title |
Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte |
| title_short |
Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte |
| title_full |
Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte |
| title_fullStr |
Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte |
| title_full_unstemmed |
Elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte |
| title_sort |
elastoplastic behavior of anisotropic, physically crosslinked hydrogel networks comprising stiff, charged fibrils in an electrolyte |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170624 |
| _version_ |
1779156625314021376 |