Effect of Nanoscale Confinement on Polymer-Infiltrated Scaffold Metal Composites

Most research on polymer composites has focused on adding discrete inorganic nanofillers to a polymer matrix to impart properties not found in polymers alone. However, properties such as ion conductivity and mechanical reinforcement would be greatly improved if the composite exhibited an interconnected network of inorganic and polymer phases. Here, we fabricate bicontinuous polymer-infiltrated scaffold metal (PrISM) composites by infiltrating polymer into nanoporous gold (NPG) films. Polystyrene (PS) and poly(2-vinylpyridine) (P2VP) films are infiltrated into the similar to 43 nm diameter NPG pores via capillary forces during thermal annealing above the polymer glass transition temperature (T-g). The infiltration process is characterized in situ using spectroscopic ellipsometry. PS and P2VP, which have different affinities for the metal scaffold, exhibit slower segmental dynamics compared to their bulk counterparts when confined within the nanopores, as measured through T-g. The more attractive P2VP shows a 20 degrees C increase in T-g relative to its bulk, while PS only shows a 6 degrees C increase at a comparable molecular weight. The infiltrated polymer, in turn, stabilizes the gold nanopores against temporal coarsening. The broad tunability of these polymer/metal hybrids represents a unique template for designing functional network composite structures with applications ranging from flexible electronics to fuel cell membranes.

Automated summary

The research focuses on fabricating bicontinuous polymer-infiltrated scaffold metal composites by infiltrating polymer into nanoporous gold films. The polymer infiltration process enhances properties such as ion conductivity and mechanical reinforcement, while also stabilizing gold nanopores against temporal coarsening. These polymer/metal hybrids offer broad tunability for designing functional network composite structures with diverse applications.