Competitive Supramolecular Associations Mediate the Viscoelasticity of Binary Hydrogels
AuthorVereroudakis, E; Bantawa, M; Lafleur, RPM; Parisi, D; Matsumoto, NM; Peeters, JW; Del Gado, E; Meijer, EW; Vlassopoulos, D
Source TitleACS Central Science
PublisherAmerican Chemical Society
University of Melbourne Author/sLafleur, Rene
AffiliationChemical and Biomolecular Engineering
Document TypeJournal Article
CitationsVereroudakis, E., Bantawa, M., Lafleur, R. P. M., Parisi, D., Matsumoto, N. M., Peeters, J. W., Del Gado, E., Meijer, E. W. & Vlassopoulos, D. (2020). Competitive Supramolecular Associations Mediate the Viscoelasticity of Binary Hydrogels. ACS Central Science, 6 (8), pp.1401-1411. https://doi.org/10.1021/acscentsci.0c00279.
Access StatusAccess this item via the Open Access location
Open Access URLPublished version
Supramolecular polymers are known to form strong and resilient hydrogels which can take up large amounts of water while exhibiting ease of processing and self-healing. They also possess similarities with networks of biological macromolecules. The combination of these features makes supramolecular polymers ideal candidates for studying mechanisms and consequences of self-assembly, which are relevant to biological materials. At the same time, this renders investigations of mixed hydrogels based on different supramolecular compounds necessary, since this substantially widens their applicability. Here, we address unusual viscoelastic properties of a class of binary hydrogels made by mixing fibrillar supramolecular polymers that are formed from two compounds: 1,3,5-benzene-tricarboxamide decorated with aliphatic chains terminated by tetra(ethylene glycol) (BTA) and a 20 kg/mol telechelic poly(ethylene glycol) decorated with the same hydrogen bonding BTA motif on both ends (BTA-PEG-BTA). Using a suite of experimental and simulation techniques, we find that the respective single-compound-based supramolecular systems form very different networks which exhibit drastically different rheology. More strikingly, mixing the compounds results in a non-monotonic dependence of modulus and viscosity on composition, suggesting a competition between interactions of the two compounds, which can then be used to fine-tune the mechanical properties. Simulations offer insight into the nature of this competition and their remarkable qualitative agreement with the experimental results is promising for the design of mixed hydrogels with desired and tunable properties. Their combination with a sensitive dynamic probe (here rheology) offer a powerful toolbox to explore the unique properties of binary hydrogel mixtures.
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