(88a) Impact of Diblock Copolymers On Droplet Coalescence, Emulsification, and Aggregation In Immiscible Homopolymer Blends | AIChE

(88a) Impact of Diblock Copolymers On Droplet Coalescence, Emulsification, and Aggregation In Immiscible Homopolymer Blends

Authors 

Green, D. - Presenter, University of Virginia
Fowler, J. - Presenter, University of Virginia
Fried, E. - Presenter, University of Virginia
Gao, R. - Presenter, Virginia Tech
Saito, T. - Presenter, Virginia Tech


Using rheo-optical techniques, we investigated the impact of interfacial wetting of symmetric diblock copolymers (BCPs) on the coalescence and aggregation of polydimethylsiloxane (PDMS) droplets in immiscible polyethylene-propylene (PEP) homopolymers. Anionic polymerization was used to synthesize well-defined matrix homopolymers and PDMS-b-PEP diblock copolymers with low polydispersity (PDI ≈ 1.02) as characterized with size exclusion chromatography and nuclear magnetic resonance spectroscopy. Blends were formulated to match the viscosities between the droplets and the matrix.  Moreover, molecular weights of these components were varied to ensure that the inner block of the copolymer inside the droplet was collapsed and dry, whereas the outer block of the copolymer outside of the droplet was stretched and wet. Droplet breakup and coalescence as well as interfacial surface tensions were measured using rheo-optical experiments with Linkam shearing stage and an optical microscope. Subsequent to droplet breakup at high shear rates, we found that the BCPs mitigated shear-induced coalescence at lower shear rates. Increased BCP stretching was inferred from surface tension measurements, which indicate that BCP stretching causes the droplet surface to saturate at lower BCP coverages in line with theoretical predictions from wet-dry brush systems.  Droplet aggregation was detected with further reductions in shear rate, which was attributed to the dewetting of the matrix from a saturated brush. Ultimately, the regions of droplet coalescence and aggregation were scaled by balancing the forces of shear with those due to the attraction between BCP-coated droplets.