Macroscale spinodal structures exhibit inertia-driven tenfold strength increase at high strain rates unlike microscale counterparts governed by constituent material sensitivity, with regime maps showing length-scale dependence analogous to fluids.
Guell Izard, J
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Fabrication and testing of 3D architected interpenetrating phase composites demonstrate that the matrix distributes stress for high-strength stable response and failure delocalization yields specific energy absorption comparable to wound fiber tubes.
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Dynamic Mechanical Response of Spinodal Architectures Across Length and Time Scales
Macroscale spinodal structures exhibit inertia-driven tenfold strength increase at high strain rates unlike microscale counterparts governed by constituent material sensitivity, with regime maps showing length-scale dependence analogous to fluids.
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Mechanics of three-dimensional micro-architected interpenetrating phase composites
Fabrication and testing of 3D architected interpenetrating phase composites demonstrate that the matrix distributes stress for high-strength stable response and failure delocalization yields specific energy absorption comparable to wound fiber tubes.