Projects per year
Cellulose nanocrystals (CNCs) can spontaneously self-assemble into chiral nematic (cn) structures, similar to natural cholesteric organizations. The latter display highly dissipative fracture propagation mechanisms given their "brick" (particles) and "mortar" (soft matrix) architecture. Unfortunately, CNCs in liquid media have strong supramolecular interactions with most macromolecules, leading to aggregated suspensions. Herein, we describe a method to prepare nanocomposite materials from chiral nematic CNCs (cn-CNCs) with strongly interacting secondary components. Films of cn-CNCs were infiltrated at various loadings with strongly interacting silk proteins and bovine serum albumin. For comparison and to determine the molecular weight range of macromolecules that can infiltrate cn-CNC films, they were also infiltrated with a range of poly(ethylene glycol) polymers that do not interact strongly with CNCs. The extent and impact of infiltration were evaluated by studying the optical reflection properties of the resulting hybrid materials (UV-vis spectroscopy), while fracture dissipation mechanisms were observed via electron microscopy. We propose that infiltration of cn-CNCs enables the introduction of virtually any secondary phase for nanocomposite formation that is otherwise not possible using simple mixing or other conventional approaches.
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- 2 Active
BioELCell: Bioproducts Engineered from Lignocelluloses: from plants and upcycling to next generation materials
Majoinen, J., Rojas Gaona, O., Dufau Mattos, B., Klockars, K., Abidnejad, R., Garcia Greca, L., Bhattarai, M., Ajdary, R., Johansson, L., Zhu, Y., Zhao, B., Ressouche, E., Tardy, B., Robertson, D., Kämäräinen, T. & Reyes Torres, G.
30/07/2018 → 31/07/2023
Project: EU: ERC grants
01/05/2018 → 31/12/2022
Project: Academy of Finland: Other research funding