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Shockwave dissipation by interface-dominated porous structures

Dana M. Dattelbaum, Axinte Ioniţă, Brian M. Patterson, Brittany Branch, Lindsey Kuettner

2020AIP Advances27 citationsDOIOpen Access PDF

Abstract

The advent of additive manufacturing (AM) has enabled topological control of structures at the micrometer scale, transforming the properties of polymers for a variety of applications. Examples include tailored mechanical responses, acoustic properties, and thermal properties. Porous polymer materials are a class of materials used for shock and blast mitigation, yet they frequently possess a lack of structural order and are largely developed and evaluated via trial-and-error. Here, we demonstrate control of shockwave dissipation through interface-dominated structures prepared by AM using 2-photon polymerization. A fractal structure with voids, or free surfaces, arranged less than 100 μm apart, allows for rarefaction interactions on the timescale of the shockwave loading. Simulations and dynamic x-ray phase contrast imaging experiments show that fractal structures with interfaces assembled within a “critical” volume reduce shockwave stress and wave velocity by over an order of magnitude within the first unit cell.

Topics & Concepts

DissipationMaterials scienceFractalPorosityPolymerPhase (matter)ThermalPorous mediumRarefaction (ecology)Fractal dimensionNanotechnologyComposite materialPhysicsGeologyMathematicsSpecies richnessQuantum mechanicsMathematical analysisThermodynamicsMeteorologyPaleontologyCellular and Composite StructuresPickering emulsions and particle stabilizationPolymer composites and self-healing
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