On the connection between the macroscopic Poisson's ratio of an isotropic discrete system and its geometrical structure
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The use of discrete material representation in numerical models is advantageous due to the straightforward way it takes into account material heterogeneity and randomness, and the discrete and orientated nature of cracks. Unfortunately, it also restricts the macroscopic Poisson's ratio and therefore narrows its applicability. Extensive work has been done in this field to overcome these limits, yet no general remedy that keeps all the positive features of the discrete model along with an arbitrary Poisson's ratio has been developed. The paper studies the Poisson's ratio of a discrete model analytically. It derives theoretical limits for cases where the geometry of the model is completely arbitrary, but isotropic in the statistical sense. It is shown that the widest limits are obtained for models with contact planes perpendicular to the contact vectors. Any deviation from perpendicularity causes the limits to shrink. A comparison of the derived equations to the results of the actual numerical model is presented. It shows relatively large deviations from the theory because the fundamental assumptions behind the theoretical derivations are largely violated in systems with complex geometry. The real shrinking of the Poisson's ratio limit is therefore less severe compared to that which is theoretically derived.
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