Granular materials, as a physical system, comprise large assemblies of discrete macroscopic particles that interact predominantly via contact forces, friction, and inelastic collisions, leading to inherently dissipative, non-equilibrium behavior. They exhibit dual solid-like and fluid-like responses depending on stress, packing fraction, and driving conditions, with phenomena such as jamming, dilatancy, force chains, and shear banding. Continuum descriptions often employ modified elasto-plastic or rheological models (e.g., μ(I) rheology), while discrete element methods resolve particle-scale dynamics. Their mechanical response is strongly history-dependent and non-linear, with emergent collective effects that challenge conventional thermodynamic and hydrodynamic formalisms.
Once a particle of matter, always a particle of matter. Or not. Thanks to a quirk of quantum physics, four known particles made up of two different quarks—such as the electrically neutral D meson composed of a charm quark ...
General Physics
Apr 12, 2024
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1591
When we take a stroll on the beach, we walk on the sand without any trouble. The sand appears solid and is difficult to compress. When we put the same sand grains in an hourglass, they behave very differently: the sand flows ...
General Physics
Apr 3, 2024
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76
Rochester researchers are uncovering the unexpected role of grain shape in the mixing of granular systems such as pharmaceuticals, cereal, and landslides.
General Physics
Feb 12, 2024
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71
