Mechanical metamaterials at the theoretical limit of isotropic elastic stiffness

Berger, Jonathan B.; Wadley, H.N.G.; McMeeking, Robert M.

doi:10.1038/nature21075

Cited by 583 publications

(305 citation statements)

References 29 publications

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“…After the pioneering work of Sigmund [Sigmund (1994)], various materials with novel physical performances have been presented, such as extreme thermal properties, maximum stiffness and fluid permeability [Challis et al (2012); Guest and Pré vost (2006)] and negative Poisson's ratio [Wang et al (2014)]. Hence, the design of micro-structured materials has become one of the most promising applications associated with topology optimization [Berger et al (2017); Cadman et al (2012); Cadman et al (2013); Osanov and Guest (2016)]. Nevertheless, the majority of these existing works are based on the material density-related interpolation schemes, while the positive features of the LSM are beneficial to the optimization of micro-structured materials, particularly considering the manufacturing.…”

Section: Introductionmentioning

confidence: 99%

Topology Optimization of Micro-Structured Materials Featured with the Specific Mechanical Properties

Gao

Luo

et al. 2019

Int. J. Comput. Methods

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Micro-structured materials consisting of an array of microstructures are engineered to provide the specific material properties. This present work investigates the design of cellular materials under the framework of level set, so as to optimize the topologies and shapes of these porous material microstructures. Firstly, the energy-based homogenization method (EBHM) is applied to evaluate the material effective properties based on the topology of the material cell, where the effective elasticity property is evaluated by the average stress and strain theorems. Secondly, a parametric level set method (PLSM) is employed to optimize the microstructural topology until the specific mechanical properties can be achieved, including the maximum bulk modulus, the maximum shear modulus and their combinations, as well as the negative Poisson's ratio (NPR). The complicated topological shape optimization of the material microstructure has been equivalent to evolve the sizes of the expansion coefficients in the interpolation of the level set function. Finally, several numerical examples are fully discussed to demonstrate the effectiveness of the developed method. A series of new and interesting material cells with the specific mechanical properties can be found.

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Section: Introductionmentioning

confidence: 99%

Topology Optimization of Micro-Structured Materials Featured with the Specific Mechanical Properties

Gao

Luo

et al. 2019

Int. J. Comput. Methods

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“…The sharply intersecting beams typically concentrate high stresses at the lattice nodes, providing a path for catastrophic crack propagation. Plate‐based designs are notably stronger and stiffer than their beam‐based counterparts, potentially alleviating some of the above challenges; however, they are still similarly affected by stress concentrations.…”

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confidence: 99%

Ultrahigh Energy Absorption Multifunctional Spinodal Nanoarchitectures

Izard

Bauer

Crook

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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“…This includes high strength and fracture toughness, low density, as well as high surface area to volume ratio deduced from the synergistic coupling effect between the geometrical structure and functional constituent materials. [1][2][3][4][5][6][7][8][9] The strength of lattices is determined not only by the order and periodicity of its structure, but also by the constituent materials. [10,11] Recently, numerous engineering materials such as Al 2 O 3, [12][13][14] Ni-P alloy, [4,15] glassy carbon, [16] copper, [17] gold, [18] and metallic glass [19,20] have been employed as constituent materials to significantly enhance the mechanical properties of pristine polymer scaffolds with respect to its strength and stiffness.…”

Section: Introductionmentioning

confidence: 99%

High‐Entropy Alloy (HEA)‐Coated Nanolattice Structures and Their Mechanical Properties

et al. 2017

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Nanolattice structure fabricated by two-photon lithography (TPL) is a coupling of size-dependent mechanical properties at micro/nano-scale with structural geometry responses in wide applications of scalable micro/nano-manufacturing. In this work, three-dimensional (3D) polymeric nanolattices are initially fabricated using TPL, then conformably coated with an 80 nm thick high-entropy alloy (HEA) thin film (CoCrFeNiAl 0.3 ) via physical vapor deposition (PVD). 3D atomic-probe tomography (APT) reveals the homogeneous element distribution in the synthesized HEA film deposited on the substrate. Mechanical properties of the obtained composite architectures are investigated via in situ scanning electron microscope (SEM) compression test, as well as finite element method (FEM) at the relevant length scales. The presented HEA-coated nanolattice encouragingly not only exhibits superior compressive specific strength of %0.032 MPa kg À1 m 3 with density well below 1000 kg m À3 , but also shows good compression ductility due to its composite nature. This concept of combining HEA with polymer lattice structures demonstrates the potential of fabricating novel architected metamaterials with tunable mechanical properties.

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Mechanical metamaterials at the theoretical limit of isotropic elastic stiffness

Cited by 583 publications

References 29 publications

Topology Optimization of Micro-Structured Materials Featured with the Specific Mechanical Properties

Topology Optimization of Micro-Structured Materials Featured with the Specific Mechanical Properties

Ultrahigh Energy Absorption Multifunctional Spinodal Nanoarchitectures

High‐Entropy Alloy (HEA)‐Coated Nanolattice Structures and Their Mechanical Properties

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