High throughput simulation tools to design porous metamaterials and processing targets for 3D printing

In many high-value applications, performance gains enabled by architected porous materials are greatest when feature length-scales push the limits of printer resolution. This implies printed components will contain a large number of microstructural and geometric defects, with inherent trade-offs between performance and reliability. This talk will present highly efficient simulation tools that embed statistical distributions of geometry, strength and ductility to quantify relationships between microscale variability and macroscopic performance. These links provide potentially powerful opportunities to quickly identify porous architectures and processing targets for significant improvements. Illustrations of these concepts will be provided for two classes of materials: (i) high temperature ceramic lattices for catalysis, where Weibull strength distributions control peak stress, and (iii) quasi-ductile refractory metal lattices being developed for aerospace, where limited ductility controls strength after damage initiation. The potential advantages and drawbacks of using models with coarse-grained descriptions will be briefly discussed, focusing on the development of optimization frameworks that embed processing science.