Convection and fluidization in a vibrated bed of powder are reproduced in a numerical simulation. In the simulation, each particle of the powder, during a collision, has a viscoelastic interaction with the other colliding particle. Because of the discreteness of the particles, this elasticity causes convection. The critical values of fluidization and convection agree with experiments. PACS numbers: 46.10,+z, 02.60.+y, 47.25.Qv Recently, many physicists [1,2] have studied the dynamics of granular materials, because these materials behave differently from continuous media like rigid, elastic, or viscous bodies. This difference is because granular materials behave in two distinct ways: as a set of particles and as continuous media. For example, granular materials under gravity can have a slope with nonzero angle (angle of repose) in the quasistationary state. Avalanches are also characteristic features in the dynamics of granular materials.One of the stranger phenomena is convection in a fluidized bed under vertical vibration [3][4][5][6][7]. A schematic figure of a typical experimental setup is shown in Fig. 1. When a vessel containing a large number of small particles is shaken strongly, heaping of the surface starts spontaneously. At the same time, convection of particles starts. Experimentalists claim that these phenomena are dynamical phase transitions.Moreover, convection is localized near the surface (surface fluidization). The depth of the convection region increases as the strength of the vibration increases. The purpose of this paper is to propose a numerical modeling to reproduce the convective motion and surface fluidization effect.Our model is a very simple one [1,8]. However, no one has pointed out that this model can reveal an instability in the fluidized bed [9]. In this model, each particle is regarded as a sphere with definite diameter d. When particles collide with one another, they penetrate into each other. During the collision, there is a viscoelastic interac-J tion between them. The equation the particles obey isx/ -xy -d X/~Xy |x/-Xy| + »/(v/-Vy) -g> where 0(x) is a step function, TV is the total number of spheres, x, is the position vector of the ith sphere, and k and 77 are the elastic constant and the viscosity coefficient, respectively, g is the acceleration of gravity and v is velocity. The step function restricts the interaction between particles to periods when the distance between two particles is less than d.In order to understand the physical meanings of the two interaction parameters k and 77, we consider the case n glass spheres • 0cm / diameter im$^6&?S&9999S8pS& 5mm io~i CPH b c 0 s CL> 0 t FIG. 1. A schematic of a typical experiment.where two spheres collide head-on with each other. In this case, they have an effective coefficient of restitution e =exp( --qn/(o). The time interval during a collision is also a function of k and 77. We call this interval the collision time, t CQ \=7t/(o [a> = (2& -77 2 ) 1/2 ]. Therefore, fixing k and 77 determines the effective coefficient of...
