Charge Transport Transitions and Scaling in Disordered Arrays of Metallic Dots
arXiv:cond-mat/0205532 · doi:10.1103/PhysRevLett.90.046802
Abstract
We examine the charge transport through disordered arrays of metallic dots using numerical simulations. We find power law scaling in the current-voltage curves for arrays containing no voids, while for void-filled arrays charge bottlenecks form and a single scaling is absent, in agreement with recent experiments. In the void-free case we also show that the scaling exponent depends on the effective dimensionality of the system. For increasing applied drives we find a transition from 2D disordered filamentary flow near threshold to a 1D smectic flow which can be identified experimentally using characteristics in the transport curves and conduction noise.
4 pages, 4 postscript figures