2018
DOI: 10.1007/s10853-018-3103-9
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Size effects in lattice-structured cellular materials: edge softening effects

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Cited by 11 publications
(9 citation statements)
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“…As mentioned earlier, the observation of size effects in a heterogeneous medium is not new, although previous reports of such effects have usually indicated that reducing overall size to that of the length scale of the underlying material heterogeneity will be accompanied by an increase in material stiffness or rigidity, behaviour described here as a conventional or positive effect which concurs with that forecast by more generalised deformation theories such as Cosserat (micropolar) elasticity. While more recent research [22,23,24] has indicated that 2D materials may exhibit both conventional positive and contradictory negative size effects when loaded in bending, the results presented here indicate that the nature of these effects may be even more involved than existing theoretical forecasts would imply or any previous work has identified. The complete inversion of the size effect from positive to negative in braced open cell cubic lattices subject to twisting while the corresponding effect in bending remains positive is an entirely new result that cannot be adequately predicted by such theories.…”
Section: Discussioncontrasting
confidence: 56%
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“…As mentioned earlier, the observation of size effects in a heterogeneous medium is not new, although previous reports of such effects have usually indicated that reducing overall size to that of the length scale of the underlying material heterogeneity will be accompanied by an increase in material stiffness or rigidity, behaviour described here as a conventional or positive effect which concurs with that forecast by more generalised deformation theories such as Cosserat (micropolar) elasticity. While more recent research [22,23,24] has indicated that 2D materials may exhibit both conventional positive and contradictory negative size effects when loaded in bending, the results presented here indicate that the nature of these effects may be even more involved than existing theoretical forecasts would imply or any previous work has identified. The complete inversion of the size effect from positive to negative in braced open cell cubic lattices subject to twisting while the corresponding effect in bending remains positive is an entirely new result that cannot be adequately predicted by such theories.…”
Section: Discussioncontrasting
confidence: 56%
“…This inversion occurs even when the redistribution of matrix material from edges to diagonals results in almost no change in volume fraction (figure 16). The causes of such size effect inversion have recently been explained for 2D layered [22] and latticed based materials [23,24] loaded in flexure. In the first case a layered material comprised of alternating stiff and compliant layers was shown to exhibit a conventional, positive size effect when the stiffer layers were located furthest from the neutral axis of bending and an opposite, negative effect when the more compliant layers were located thus.…”
Section: Numerical Resultsmentioning
confidence: 99%
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“…Note that the investigated size effects result from the bending deformation of the cantilever beam. Nevertheless, it should be mentioned that the mechanism of size effects could also be the result of the so-called edge effects [58,87], which lead to a softer response of structures. Therefore, in order to understand size effects, softening effects must be studied, and this will be left for the future.…”
Section: Discussionmentioning
confidence: 99%
“…From the perspective of pile impedance and foundation settlement, Liu et al studied the size effect of the rigid pile composite foundation [20]. Yoder et al found that the dimensional effect of porous material was related to the bending strain energy [21]. Lee & Han studied the size effect of the foundation, and they found that the bearing capacity coefficient decreased with increase of the foundation width [22].…”
Section: State Of the Artmentioning
confidence: 99%