Engineered Damping: From Impact Mitigation to Enhanced Actuation

Superior specific energy absorption, strength, and stiffness are critical for protective materials that are used in lightweight armor and spacecraft. Nanofibrous materials offer an opportunity to synergistically exploit intrinsic nanofiber properties and inter-fiber interactions for dynamic performance enhancement. We show synergistic performance improvement with failure retardation in carbon nanotube (CNT) mats by augmenting the weak van der Waal interactions with stronger and reconfigurable interfacial hydrogen bonds formed by introducing aramid nanofiber (ANF) links between CNTs. Under supersonic microprojectile impacts, strengthened dynamic interactions in ANF-CNT mats enhance their specific energy absorption up to 3.6 MJ/kg—outperforming other nanomaterials and widely used bulk Kevlar fiber-based protective materials.

The dissipation, on the other hand, is considered undesirable when designing actuators or metamaterials for high-quality wave guiding. In contrast, we demonstrate an unusual reconfigurable enhancement in actuation force using engineered damping in a novel non-Hermitian metamaterial. The actuation force is enhanced up to twofold at a constant quality factor when we bring the system to operate at the proximity to an exceptional point—a singularity where the eigenvalues of a system and its corresponding eigenvectors coalesce. The ability to enhance forces by virtue of an engineered passive material can lead to lightweight autonomous actuation devices.