Aggregation of magnetic holes in a rotating magnetic field

Abstract

We have experimentally investigated field induced aggregation of nonmagnetic particles confined in a magnetic fluid layer when rotating magnetic fields were applied. After application of a magnetic field rotating in the plane of the fluid layer, the single particles start to form two-dimensional (2D) clusters, like doublets, triangels, and more complex structures. These clusters aggregated again and again to form bigger clusters. During this nonequilibrium process, a broad range of cluster sizes was formed, and the scaling exponents, z and z', of the number of clusters N(t) tz'and average cluster size S(t) tz were calculated. The process could be characterized as diffusion limited cluster-cluster aggregation. We have found that all sizes of clusters that occured during an experiment, fall on a single curve as the dynamic scaling theory predicts. Hovewer, the characteristic scaling exponents z',\: z and crossover exponents were not universal. A particle tracking method was used to find the dependence of the diffusion coefficients Ds on cluster size s. The cluster motions show features of Brownian motion. The average diffusion coefficients <Ds> depend on the cluster sizes s as a power law <Ds> sγ where values of γ as different as γ=-0.620.19 and $γ=-2.080. were found in two of the experiments.