Evidence for an in Situ Developed Polymer Phase in Ionic Elastomers

Citations Over TimeTop 10% of 2014 papers

Abstract

The overall mechanical performance of ionic elastomers, such as carboxylated nitrile rubber (XNBR), is largely governed by ionic clusters formed during the cross-linking of the elastomers with zinc oxide. These ionic aggregates promote microphase separation and show additional high-temperature relaxation behavior in dynamic mechanical analysis. In this study, the nature of these ionic aggregates is explored for the first time. We find that some zinc-containing compounds, such as zinc–aluminum-layered double hydroxide and zinc chloride, do not exhibit any extra high-temperature dynamic mechanical relaxation processes, although ionic cross-linking reactions with XNBR occur with all of these zinc compounds. Detailed analysis by Fourier-transform infrared spectroscopy and dynamic mechanical analysis revealed that this high-temperature relaxation behavior does not originate from ionic cross-linking but is associated with the formation of an additional zinc-enriched polymer phase that arises due to reactions between carboxylic groups and zinc oxide. Infrared spectroscopic investigation indicates further that a tetrahedrally coordinated complex facilitates the formation of a zinc–carboxylic polymeric network. Clear microphase separation of the ionic polymer in the elastomer could be directly visualized by transmission electron microscopy for the first time.

Related Papers

• → A highly stretchable and self-healing hydroxy-terminated polybutadiene elastomer(2020)28 cited
• → Polyurethane elastomers containing polybutadiene and aliphatic diols: Structure‐property relationships(1987)38 cited
• → Studies on thermodynamic compatibility of nitrile rubber and polybutadiene by inverse gas chromatography(1995)4 cited
• → On the [13C]T1 ρ behavior of some elastomers(1997)1 cited