Enhanced Impact Mitigation via 3D-Multilayered Material Architectures

TL;DR

This paper introduces a multilayered material design that combines different architectures to significantly improve impact mitigation, outperforming single-architecture lattices in energy dissipation.

Contribution

It demonstrates a novel heterostructure approach using alternating monolithic and beam-based layers for enhanced impact resistance in lightweight materials.

Findings

Heterostructures outperform single-architecture lattices by >50% in energy dissipation.

Layered designs enable predictable impact responses.

Wave-propagation and finite element analyses link structure to impact behavior.

Abstract

Materials designed by nature commonly exhibit functional grading and laminated structures, particularly when intended for enhanced impact protection. Synthetic materials have also found success in exploiting this concept with fully dense but spatially varying architectures, as is the case with advanced fiber-based composites. In the lightweight materials space, porous architected materials have shown benefits for extreme impact mitigation, proving to be advantageous in dissipating large amounts of energy per unit mass, but rarely harness the benefits of layering or functional grading in designs. Here, a design paradigm for lightweight multilayered materials towards high impact-mitigation efficacy is demonstrated, showing that the use of alternating monolithic and beam-based architectures leads to enhanced and predictable responses under extreme conditions. These layered, mass-equivalent `heterostructures' with different ordering and proportions of octet and monolithic layers outperform single-architecture lattices on a mass-normalized energy dissipation basis by >50% when subjected to supersonic microparticle impact. Through analysis that combines wave-propagation analysis, nonlinear finite element simulations, and post-impact crater reconstruction, layer-by-layer mechanical properties are mapped to crater formation and energy dissipation behaviors. This heterostructure design framework offers a simple approach towards tuning failure and impact resistance of materials for protective applications from Whipple shields to sports equipment.