The Role of a Diluent in Deformation-Induced Bonding of Glassy Polymer Bidisperse Blends
Abstract
Bonding between polymers below the glass transition temperature through molecular-scale dilatation (or densification)-based interdiffusion of macromolecules has recently been introduced. In this mechanism, short timeframe plastic deformation enables polymer chains to interdiffuse and form entanglements at the interface, facilitating rapid bonding below the glass transition temperature (Tg). Here, we are addressing the role of a lower molecular weight diluent in bonding polymer interfaces of bidisperse blends through deformation-induced bonding (DIB) at temperatures well below both the surface and bulk glass transition temperatures, Tgs and Tgb, respectively, by using molecular simulations. These simulations reveal that addition of the diluent (φ20\%) drastically enhances the number of chain-ends at the interfacial region compared to a pure glass sample (φ=0\%) during deformation below Tgs, which improves the possibility of opposite side entanglement formation. The changes in stress-strain response of debonded samples correlate with the normalized entanglement density. Likewise, the maximum interfacial fracture energy GI,max of debonded samples is correlated with the diluent concentration (φ), below Tgs. Furthermore, the optimization of material and process conditions for DIB has yielded a notable advancement for the conditions tested here: achieving a higher bonding strength, approximately one-third of the bulk, all while remaining below Tg.
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