A Theory of Cooperative Diffusion in Dense Granular Flows

@misc{citeulike:1211492, abstract = {Dilute granular flows are routinely described by collisional kinetic theory, but dense flows require a fundamentally different approach, due to long-lasting, many-body contacts. In the case of silo drainage, many continuum models have been developed for the mean flow, but no realistic statistical theory is available. Here, we propose that particles undergo cooperative displacements in response to diffusing ``spots'' of free volume. The typical spot size is several particle diameters, so cages of nearest neighbors tend to remain intact over large distances. The spot hypothesis relates diffusion and cage-breaking to volume fluctuations and spatial velocity correlations, in agreement with new experimental data. It also predicts density waves caused by weak spot interactions. Spots enable fast, multiscale simulations of dense flows, in which a small, internal relaxation enforces packing constraints during spot-induced motion. In the continuum limit of the model, tracer diffusion is described by a new stochastic differential equation, where the drift velocity and diffusion tensor are coupled non-locally to the spot density. The same mathematical formalism may also find applications to glassy relaxation, as a compelling alternative to void (or hole) random walks.}, author = {Bazant, Martin Z. }, citeulike-article-id = {1211492}, eprint = {cond-mat/0307379}, keywords = {flow, grain, qualifier, theory}, month = {May}, posted-at = {2008-03-24 22:43:08}, priority = {2}, title = {A Theory of Cooperative Diffusion in Dense Granular Flows}, url = {http://arxiv.org/abs/cond-mat/0307379}, year = {2004} }

TY - ELEC ID - citeulike:1211492 L3 - citeulike-article-id:1211492 TI - A Theory of Cooperative Diffusion in Dense Granular Flows N2 - Dilute granular flows are routinely described by collisional kinetic theory, but dense flows require a fundamentally different approach, due to long-lasting, many-body contacts. In the case of silo drainage, many continuum models have been developed for the mean flow, but no realistic statistical theory is available. Here, we propose that particles undergo cooperative displacements in response to diffusing ``spots'' of free volume. The typical spot size is several particle diameters, so cages of nearest neighbors tend to remain intact over large distances. The spot hypothesis relates diffusion and cage-breaking to volume fluctuations and spatial velocity correlations, in agreement with new experimental data. It also predicts density waves caused by weak spot interactions. Spots enable fast, multiscale simulations of dense flows, in which a small, internal relaxation enforces packing constraints during spot-induced motion. In the continuum limit of the model, tracer diffusion is described by a new stochastic differential equation, where the drift velocity and diffusion tensor are coupled non-locally to the spot density. The same mathematical formalism may also find applications to glassy relaxation, as a compelling alternative to void (or hole) random walks. KW - flow KW - grain KW - qualifier KW - theory AU - Bazant, Martin PY - 2004/May/08/ UR - http://arxiv.org/abs/cond-mat/0307379 ER -