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Stress transmission through a model system of cohesionless elastic grains

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  • Miguel Da Silva

    (Laboratoire des Milieux Désordonnés et Hétérogènes (UMR 7603 CNRS), Case 86, Université P. et M. Curie)

  • Jean Rajchenbach

    (Laboratoire des Milieux Désordonnés et Hétérogènes (UMR 7603 CNRS), Case 86, Université P. et M. Curie)

Abstract

Understanding the mechanical properties of granular materials is important for applications in civil and chemical engineering, geophysical sciences and the food industry1, as well as for the control or prevention of avalanches and landslides2. Unlike continuous media, granular materials lack cohesion, and cannot resist tensile stresses. Current descriptions of the mechanical properties of collections of cohesionless grains have relied either on elasto-plastic models classically used in civil engineering3, or on a recent model involving hyperbolic equations4,5. The former models suggest that collections of elastic grains submitted to a compressive load will behave elastically. Here we present the results of an experiment on a two-dimensional model system—made of discrete square cells submitted to a point load—in which the region in which the stress is confined is photoelastically visualized as a parabola. These results, which can be interpreted within a statistical framework, demonstrate that the collective response of the pile contradicts the standard elastic predictions and supports a diffusive description of stress transmission. We expect that these findings will be applicable to problems in soil mechanics, such as the behaviour of cohesionless soils or sand piles.

Suggested Citation

  • Miguel Da Silva & Jean Rajchenbach, 2000. "Stress transmission through a model system of cohesionless elastic grains," Nature, Nature, vol. 406(6797), pages 708-710, August.
    • Handle: RePEc:nat:nature:v:406:y:2000:i:6797:d:10.1038_35021023
    DOI: 10.1038/35021023
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    Cited by:

    1. Li, Peng & Li, Yinping & Shi, Xilin & Zhao, Kai & Liang, Xiaopeng & Ma, Hongling & Yang, Chunhe & Liu, Kai, 2022. "Compaction and restraining effects of insoluble sediments in underground energy storage salt caverns," Energy, Elsevier, vol. 249(C).

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