Litcius/Paper detail

Aza-Michael Chemistry for PDMS-Based Covalent Adaptable Elastomers: Design and Dual Role of the Silica Filler

Loc Tan Nguyen, Chiel Mertens, Filip Du Prez

2024Macromolecules22 citationsDOIOpen Access PDF

Abstract

In this study, polydimethylsiloxane (PDMS)-based covalent adaptable networks have been prepared in a one-pot, catalyst-free way in which dynamic β-amino esters (BAEs) are introduced via aza-Michael addition between available acrylate/amine-terminated PDMS-compounds. The straightforward introduction of those BAE-groups in such high-value elastomers provides the ability to relax the applied stress at elevated temperatures and hence the capability of reshaping the networks by compression molding at least 5 times without significant changes in properties. Moreover, the mechanical and dynamic properties are tunable by varying the cross-linker and/or filler content. Interestingly, the utilization of silica fillers not only enhances the network formation and mechanical properties but also accelerates the exchange reactions, resulting in twice faster stress relaxation at elevated temperatures while maintaining creep resistance at service temperatures.

Topics & Concepts

PolydimethylsiloxaneElastomerMaterials scienceStress relaxationCovalent bondAcrylateFiller (materials)Polymer chemistryDynamic covalent chemistryHydrosilylationRelaxation (psychology)Network structurePolymerChemical engineeringCreepComposite materialCatalysisMoleculeChemistryOrganic chemistryCopolymerPsychologyMachine learningComputer scienceSocial psychologyEngineeringSupramolecular chemistryPolymer composites and self-healingSynthetic Organic Chemistry MethodsAdvanced Sensor and Energy Harvesting Materials