Multi-morphology lattices lead to improved plastic energy absorption

Alberdi, Ryan; Dingreville, Rémi; Robbins, Joshua; Walsh, Timothy; White, Benjamin C.; Jared, Bradley; Boyce, Brad L.

doi:10.1016/j.matdes.2020.108883

Title: Multi-morphology lattices lead to improved plastic energy absorption

Journal Article · 20 June 2020 · Materials & Design

DOI: https://doi.org/10.1016/j.matdes.2020.108883 · OSTI ID:1634146

Alberdi, Ryan ^[1]; Dingreville, Rémi ^[1]; Robbins, Joshua ^[1]; Walsh, Timothy ^[1]; White, Benjamin C. ^[1]; Jared, Bradley ^[1]; Boyce, Brad L. ^[1]

Sandia National Lab. (SNL-NM), Albuquerque, NM (United States)

While lattice metamaterials can achieve exceptional energy absorption by tailoring periodically distributed heterogeneous unit cells, relatively little focus has been placed on engineering heterogeneity above the unit-cell level. In this work, the energy-absorption performance of lattice metamaterials with a heterogeneous spatial layout of different unit cell architectures was studied. Such multi-morphology lattices can harness the distinct mechanical properties of different unit cells while being composed out of a single base material. A rational design approach was developed to explore the design space of these lattices, inspiring a non-intuitive design which was evaluated alongside designs based on mixture rules. Fabrication was carried out using two different base materials: 316L stainless steel and Vero White photopolymer. Results show that multi-morphology lattices can be used to achieve higher specific energy absorption than homogeneous lattice metamaterials. Additionally, it is shown that a rational design approach can inspire multi-morphology lattices which exceed rule-of-mixtures expectations.

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