Elastic properties of mono‐ and polydisperse two‐dimensional crystals of hard‐core repulsive Yukawa particles

Narojczyk, Jakub W.; Pigłowski, Paweł M.; Wojciechowski, Krzysztof W.; Tretiakov, Konstantin V.

doi:10.1002/pssb.201552242

Cited by 7 publications

(5 citation statements)

References 43 publications

(69 reference statements)

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“…52 Studies of two-dimensional Yukawa crystals revealed that this system is not auxetic. 53 However, as mentioned before, the three-dimensional Yukawa crystals exhibit negative Poisson's ratio in the [110][1% 10]-direction and are partial auxetics, supposedly with a similar mechanism of partial auxeticity as discussed for fcc crystals by Milstein and Huang 54 and as found in the hard sphere model near melting 55 and near close packing 56 and as reported by Baughman et al for some fcc metals. 49 Moreover, the value of Poisson's ratio can be modified by changing the screening length -an increase of the screening length causes Poisson's ratio to decrease.…”

Section: Introductionmentioning

confidence: 61%

Auxeticity enhancement due to size polydispersity in fcc crystals of hard-core repulsive Yukawa particles

et al. 2017

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The Poisson's ratio of the fcc hard-core repulsive Yukawa crystals with size polydispersity was determined by Monte Carlo simulations in the isothermal-isobaric ensemble. The effect of size polydispersity on the auxetic properties of Yukawa crystals has been studied. It has been found that an increase of particle size polydispersity causes a decrease of the Poisson's ratio in auxetic directions as well as appearance of a negative Poisson's ratio in formerly non-auxetic directions. A measure of auxeticity was introduced to estimate quantitatively an enhancement of auxetic properties in polydisperse Yukawa crystals. The proposed measure of auxeticity can be applied to appraise the auxeticity of any studied system.

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Section: Introductionmentioning

confidence: 61%

Auxeticity enhancement due to size polydispersity in fcc crystals of hard-core repulsive Yukawa particles

et al. 2017

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“…Indeed, it has earlier been shown that purely auxetic and partially auxetic systems can be constructed from rigid particles, i.e. by means of purely geometrical interactions [72][73][74][75].…”

Section: Introductionmentioning

confidence: 99%

Auxetic properties of a tangram-inspired metamaterial

Lim

2023

Eng. Res. Express

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This paper explores a new anisotropic auxetic system that consists of rotating rhombi and right triangles by inspiration from tangram pieces. The Poisson’s ratio was developed by geometrical analysis on the representative unit with prescribed boundary requirements. Upon assigning rotational stiffness to the hinges, the Young’s modulus was established by matching the potential energy stored in the spiral springs with the strain energy of the deformation for the homogenized continuum. Results indicate that the on-axes Poisson’s ratio and dimensionless Young’s moduli are governed by the shapes and separation angles of the rigid units which, in turn, determine the dimension of the representative unit of the metamaterial. For the special case where the Poisson’s ratio is -1 when stretched on either axis, the Young’s moduli are equal. For this special case, the separation angles and the on-axes Young’s moduli increase monotonically with the shape descriptor of the rigid units. The capability of combining rotating rigid units of quadrilateral and triangular shapes suggests that new combinations of mechanical properties can be designed from rotation-based auxetic systems.

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“…[1][2][3][4][5][6] Yet the majority of auxetic materials are artificially made with the microstructure engineered to exhibit negative Poisson's ratio(s) at macroscopic level. These include re-entrant honeycomb structures, [7][8][9] tethered-nodule networks, [10][11][12] chiral systems, [13][14][15][16][17] rotating rigid and semi-rigid units, [18][19][20][21][22] interlocking units, [23,24] some granular materials, [24][25][26] molecular systems, [8,[27][28][29][30][31][32][33] foldable structures, [34] foams with missing ribs, [35] perforated sheets, [36][37][38][39][40] auxetic lattices, [41,42] beam and pivots networks, [43] multiphase composites with re-entrant microstructure, [44,45] multilayered composite...…”

Section: Introductionmentioning

confidence: 99%

“…Yet the majority of auxetic materials are artificially made with the microstructure engineered to exhibit negative Poisson's ratio(s) at macroscopic level. These include re‐entrant honeycomb structures, tethered‐nodule networks, chiral systems, rotating rigid and semi‐rigid units, interlocking units, some granular materials, molecular systems, foldable structures, foams with missing ribs, perforated sheets, auxetic lattices, beam and pivots networks, multiphase composites with re‐entrant microstructure, multilayered composites and hollow sphere stacks . Also conventional (positive Poisson's ratio) foam can be converted into the auxetic one using heat treatment, thermo‐forming, and compaction .…”

Section: Introductionmentioning

confidence: 99%

Behavior of Extreme Auxetic and Incompressible Elastic Materials

Dyskin

Pasternak

2017

Physica Status Solidi (b)

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We investigate auxetic isotropic elastic materials with the Poisson's ratio of exactly −1 and isotropic materials with the Poisson's ratio of near 0.5 (incompressible). In both cases the energy is not positive definite, which can lead to the material instability. In incompressible materials, the instability manifests itself in the emergence of non‐uniform displacement distribution. Investigation of the behavior of such materials with respect to damage or crack accumulation is based on the notion that during the instantaneous process of fracture formation, the fracture acts as a negative stiffness element; after the fracture is formed, it immediately turns into a conventional fracture with usual positive stiffness. We demonstrate that the cracks formed due to tensile or combined tensile and shear fracturing of the material are capable of momentarily bringing the Poisson's ratio of nearly incompressible material to 0.5, which instantaneously turns the material into unstable. On the other hand, the formation of shear cracks leads to reduction in the Poisson's ratio bringing the material away from the point of instability. Opposite to this, cracks of all kinds do not change the Poisson's ratio in extreme auxetics (the Poisson's ratio equal to −1). Thus the auxetic materials remain stable with respect to fracture formation.

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Elastic properties of mono‐ and polydisperse two‐dimensional crystals of hard‐core repulsive Yukawa particles

Cited by 7 publications

References 43 publications

Auxeticity enhancement due to size polydispersity in fcc crystals of hard-core repulsive Yukawa particles

Auxeticity enhancement due to size polydispersity in fcc crystals of hard-core repulsive Yukawa particles

Auxetic properties of a tangram-inspired metamaterial

Behavior of Extreme Auxetic and Incompressible Elastic Materials

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