Pieter Samyn

Title: Interface design for circular bio-composites: Sensing the failure

Abstract:

The performance of fiber-reinforced polymer composites is determined by the interface compatibility. In particular, the hydrophilic nature of cellulose fibers dispersed in a hydrophobic matrix requires additional surface modification as traditionally done with chemical surface grafting and hazardous solvents. Taking into account the environmental friendliness of cellulose composites, however, more sustainable routes are required to operate under aqueous environment and utilization of biopolymer substitution. Therefore, the use of polydopamine as adhesive mediator has been explored in providing a general platform to functionalize cellulose fibers. In this presentation, different conformations for surface modifications of cellulose fibers with dopamine are illustrated for enhancing compatibility. This is done either by self-polymerization of polydopamine into a compatible surface layer and/or the self-assembly of dopamine functional groups into vesicular structures that are physically adsorbed at the cellulose surface. After a study on the surface adhesion of modified cellulose fibers, they were incorporated in PMMA matrix through solution casting. The local adhesive properties of the modified cellulose fibers were probed by atomic force microscopy and seem to contribute to higher interfacial shear strength. This was confirmed by the single-fiber pull out tests at macroscale indicating an optimum concentration of nanoparticles at the cellulose surface. The tensile strength and elongation at break of the composites were function of the degree of surface modification and superior to untreated fibers. In addition, the nanoparticles show colorimetric and fluorescent response to mechanical shear stresses providing an evaluation tool to explore the interface phenomena upon failure of the PMMA composite. The reversibility of the interface for debonding can be regulated through solvatation under appropriate pH conditions.

Audience Take Away:

• Novel concept for regulating interface adhesion in biocomposites
• Analytical evaluation of the local stress state in the interface
• Analytical prediction of failure mechanisms in the interfaces
• Debonding of the interface for improved recyclability of fibers and matrix

Biography:

Dr. ir. Pieter Samyn received Ph.D. in Materials Science and Engineering 2007 at Ghent University in the field of polymer tribology and subsequently developed an academic career with several post-doc and assistant professor positions at University Ghent, Freiburg, and Hasselt. In 2021, he joined the collective research center Sirris as a Senior Research Engineer in Circular Economy and Renewable Materials. He has broad experience on the synthesis, processing and analytical characterization of bio-based materials for nanocomposites and coatings. His analytical experiences focus on several types of spectroscopy, thermal analysis, elemental analysis and chromatography. His research focusses on surface functionalization of natural materials and papers in particular for engineering applications,  subsequently leading research projects on bio-inspired adhesion mechanisms, bio-based barrier-coatings for packaging papers and the development of functional (nano)composite materials from bio-based building blocks (cellulose, biopolymers) including melt-processing conditions. His work was awarded with a Robert-Bosch Juniorprofessorship, Baden-Wurttemberg Juniorprofessorenprogramm, Heinz-Maier Leibnitz Preis, FRIAS Fellowship and visiting scholar stependia at several research institutes. Currently, he assists companies in implementation of bio-based coatings and paints for industrial application.