Energy dissipation mechanisms in hollow metallic microlattices

Salari-Sharif, Ladan; Schaedler, Tobias A.; Valdevit, Lorenzo

doi:10.1557/jmr.2014.226

Cited by 75 publications

(57 citation statements)

References 41 publications

(55 reference statements)

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“…This is due to significantly lower values of yield (failure) strain,

ε_{normaly}

,for metals and ceramics, which results in extremely thin hinges in order to avoid hinge failure. The proposed shape‐reconfigurable material overlays part of performance region of elastomers and outperforms previously proposed micro‐lattices with substantial recoverability from large strains including ultralight and hierarchical architected materials . Only the architected materials presented in this work, however, are multistable.…”

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confidence: 77%

Multistable Shape‐Reconfigurable Architected Materials

et al. 2016

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Multistable shape-reconfigurable architected materials encompassing living hinges and enabling combinations of high strength, high volumetric change, and complex shape-morphing patterns are introduced. Analytical and numerical investigations, validated by experiments, are performed to characterize the mechanical behavior of the proposed materials. The proposed architected materials can be constructed from virtually any base material, at any length scale and dimensionality.

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“…This is due to significantly lower values of yield (failure) strain,

ε_{normaly}

mentioning

confidence: 77%

Multistable Shape‐Reconfigurable Architected Materials

et al. 2016

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“…However, in all of these systems there are challenges associated with either reusability or rate dependency. Most recently, mechanical metamaterials have been fabricated in novel geometries to realize recoverable energy‐absorbing behavior in elastic systems, suggesting novel strategies for mechanical dissipation of energy.…”

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confidence: 99%

Multistable Architected Materials for Trapping Elastic Strain Energy

et al. 2015

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3D printing and numerical analysis are combined to design a new class of architected materials that contain bistable beam elements and exhibit controlled trapping of elastic energy. The proposed energy-absorbing structures are reusable. Moreover, the mechanism of energy absorption stems solely from the structural geometry of the printed beam elements, and is therefore both material- and loading-rate independent.

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“…So far, lightweight nanoarchitected materials have mostly been designed for either high deformability or high strength, with true multifunctionality remaining a major challenge. Elastic beam buckling allows repeatable recoverability from large‐strain compression in low density lattices, providing high damping capability . However, those buckling mechanisms and high imperfection sensitivity cause low specific strength, i.e., the strength‐to‐weight ratio, and therefore poor energy absorption during deformation.…”

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confidence: 99%

Ultrahigh Energy Absorption Multifunctional Spinodal Nanoarchitectures

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et al. 2019

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Nanolattices are promoted as next‐generation multifunctional high‐performance materials, but their mechanical response is limited to extreme strength yet brittleness, or extreme deformability but low strength and stiffness. Ideal impact protection systems require high‐stress plateaus over long deformation ranges to maximize energy absorption. Here, glassy carbon nanospinodals, i.e., nanoarchitectures with spinodal shell topology, combining ultrahigh energy absorption and exceptional strength and stiffness at low weight are presented. Noncatastrophic deformation up to 80% strain, and energy absorption up to one order of magnitude higher than for other nano‐, micro‐, macro‐architectures and solids, and state‐of‐the‐art impact protection structures are shown. At the same time, the strength and stiffness are on par with the most advanced yet brittle nanolattices, demonstrating true multifunctionality. Finite element simulations show that optimized shell thickness‐to‐curvature‐radius ratios suppress catastrophic failure by impeding propagation of dangerously oriented cracks. In contrast to most micro‐ and nano‐architected materials, spinodal architectures may be easily manufacturable on an industrial scale, and may become the next generation of superior cellular materials for structural applications.

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Energy dissipation mechanisms in hollow metallic microlattices

Cited by 75 publications

References 41 publications

Multistable Shape‐Reconfigurable Architected Materials

Multistable Shape‐Reconfigurable Architected Materials

Multistable Architected Materials for Trapping Elastic Strain Energy

Ultrahigh Energy Absorption Multifunctional Spinodal Nanoarchitectures

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