📝 SummarXiv

Abstract

Vitrimers are a class of crosslinked polymer that are capable of undergoing bond exchange reactions, allowing structural reorganization while maintaining overall network integrity. Two key features that are particularly relevant when this vitrimer concept is used to compatibilize immiscible polymer blends are how they affect the (i) bulk polymer density and (ii) interfacial activity of the crosslink groups. To probe these issues, we model both a bulk polymer melt and a thin film of a polymer melt both with explicit small molecular crosslinkers, in the associative limit, i.e., when the number of crosslinks are fixed. We show that the bulk density and the distribution of stickers within a polymer matrix is strongly influenced by their size and interactions with the base polymer. Specifically, when the crosslinkers are chemically compatible with the base polymer, then the overall packing fraction increases, regardless of crosslinker size, while it decreases when crosslinkers are incompatible with the polymers. Similarly, the crosslinkers segregate preferentially to the polymer-air interface when they are incompatible with the polymer chains, leading to a reduction interfacial tension. Thus, these incompatible crosslinkers should help in affecting both the miscibility of polymer blends, and also their compatibility by creating copolymer structures at the interface. These results demonstrate the key role of crosslinker-polymer interactions and crosslinker size on the structural and interfacial properties of vitrimer melts.