Stiff auxetics: Hierarchy as a route to stiff, strong lattice based auxetic meta-materials

Rayneau-Kirkhope, Daniel

doi:10.1038/s41598-018-30822-x

Cited by 52 publications

(22 citation statements)

References 58 publications

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“…Indeed, the limitations of the two length scales approach have been also recognized by other metamaterials communities. For example, a number of hierarchical mechanical metamaterials 25,26 with extraordinary and otherwise impossible combination of properties, such as high stiffness and auxetic behavior 27 have recently appeared in the literature.…”

Section: Introductionmentioning

confidence: 99%

Meta-biomaterials

Zadpoor

2020

Biomater. Sci.

105

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Section: Introductionmentioning

confidence: 99%

Meta-biomaterials

Zadpoor

2020

Biomater. Sci.

105

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“…The investigation was primarily focused on exploring the merits of introducing hierarchical triangular truss-like components within the rotating unit and analysing the effects of these structural frameworks on the mechanical properties of the studied systems. Previous studies on other hierarchical auxetic systems have shown that the introduction of hierarchy in such structures may be used to obtain enhanced mechanical properties and/or provide structural stability through smart design [23][24][25][26][27][28][29][30]. Hierarchical structures, which are defined as structures which are themselves made from structures [31], are not limited solely to fractal or fractal-like systems [25,32,33], but may also include the use of different geometries and mechanisms at separate hierarchical levels aimed at conferring additional enhanced properties to the system.…”

Section: Introductionmentioning

confidence: 99%

Lightweight mechanical metamaterials designed using hierarchical truss elements

Mizzi

Spaggiari

2020

Smart Mater. Struct.

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Rotating unit systems constitute one of the main classes of auxetic metamaterials. In this work, a new design procedure for lightweight auxetic systems based on this deformation mechanism is proposed through the implementation of a hierarchical triangular truss network in place of a full block of material for the rotating component of the system. Using numerical simulations in conjunction with experimental tests on 3D printed prototypes, the mechanical properties of six types of auxetic structures, which include a range of rotating polygons and chiral honeycombs, were analysed under the application of small tensile loads. The results obtained show that there is almost no difference in the Poisson's ratios obtained from the regular, full structures and the ones made from triangular truss systems despite the latter, in some cases, being 80% lighter than the former. This indicates that these systems could be ideal candidates for implementation in applications requiring lightweight auxetic metamaterial systems such as in the aerospace industry.

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“…It should be noted that materials with negative Poisson's ratio, negative thermal expansion, negative compressibility, and other anomalous characteristics attract considerable attention of researchers because they are interesting from the theoretical standpoint and have a potential in applications …”

Section: Introductionmentioning

confidence: 99%

Delocalized Nonlinear Vibrational Modes in Graphene: Second Harmonic Generation and Negative Pressure

Korznikova

Shcherbinin

Ryabov

et al. 2018

Physica Status Solidi (b)

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With the help of molecular dynamics simulations, delocalized nonlinear vibrational modes (DNVM) in graphene are analyzed. Such modes are dictated by the lattice symmetry, they are exact solutions to the atomic equations of motion, regardless the employed interatomic potential and for any mode amplitude (though for large amplitudes they are typically unstable). In this study, only one-and two-component DNVM are analyzed, they are reducible to the dynamical systems with one and two degrees of freedom, respectively. There exist 4 one-component and 12 two-component DNVM with in-plane atomic displacements. Any two-component mode includes one of the one-component modes. If the amplitudes of the modes constituting a two-component mode are properly chosen, periodic in time vibrations are observed for the two degrees of freedom at frequencies ω and 2ω, that is, second harmonic generation takes place. For particular DNVM, the higher harmonic can have frequency nearly two times larger than the maximal frequency of the phonon spectrum of graphene. Excitation of some of DNVM results in the appearance of negative in-plane pressure in graphene. This counterintuitive result is explained by the rotational motion of carbon hexagons. Our results contribute to the understanding of nonlinear dynamics of the graphene lattice.

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Stiff auxetics: Hierarchy as a route to stiff, strong lattice based auxetic meta-materials

Cited by 52 publications

References 58 publications

Meta-biomaterials

Meta-biomaterials

Lightweight mechanical metamaterials designed using hierarchical truss elements

Delocalized Nonlinear Vibrational Modes in Graphene: Second Harmonic Generation and Negative Pressure

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