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Heterogeneous Local Dynamics in Mussel-Inspired Elastomers

Marianna Spyridakou, Elpida Iliopoulou, Katerina Peponaki, Stelios Alexandris, Emmanouela Filippidi, George Floudas

2023Macromolecules16 citationsDOI

Abstract

Materials with increased mechanical strength and toughness bearing mussel-inspired iron–catechol complexes and network architectures exhibit several dynamic features, e.g., high and broad glass-“transition” temperature, not explored so far. By combining differential scanning calorimetry and dielectric spectroscopy, the latter as a function of temperature and pressure, we have explored the increase in the glass temperature, T g, and the concomitant increase in the breath of T g in bioinspired networks bearing one (covalent) or two (covalent and coordination) types of cross-links. Cross-linked networks experience heterogeneous segmental dynamics that are responsible for the broad T g range observed in the thermal measurements. The two distinct dynamics reflect the relaxation of segments in the vicinity versus more distant cross-linked units. The various topologies are shown to have different fragilities and tend to form stronger glasses with increasing network topology. In addition, the ionic conductivity is influenced by the segmental dynamics and the increased T g in the networks. These features (reduced specific heat step, Δ c p, at T g and “strong” dynamic behavior) are also found in permanently cross-linked polymers with dynamic network topology known as vitrimers . The similarities in the two network systems are discussed.

Topics & Concepts

Glass transitionDifferential scanning calorimetryDynamic mechanical analysisIonic bondingMaterials scienceRelaxation (psychology)ElastomerToughnessTopology (electrical circuits)PolymerCovalent bondMolecular dynamicsFragilityNetwork topologyChemical physicsChemistryComposite materialThermodynamicsPhysicsPhysical chemistryComputer scienceComputational chemistryOrganic chemistryIonSocial psychologyOperating systemMathematicsCombinatoricsPsychologyPolymer composites and self-healingAdvanced Polymer Synthesis and CharacterizationPolymer Nanocomposites and Properties