Origins of Anomalous Transport in Disordered Media: Structural and Dynamic Controls

Abstract

We quantitatively identify the origin of anomalous transport in a representative model of a heterogeneous system---tracer migration in the complex flow patterns of a lognormally distributed hydraulic conductivity (K) field. The transport, determined by a particle tracking technique, is characterized by breakthrough curves; the ensemble averaged curves document anomalous transport in this system, which is entirely accounted for by a truncated power-law distribution of local transition times (t) within the framework of a continuous time random walk. Unique to this study is the linking of (t) directly to the system heterogeneity. We assess the statistics of the dominant preferred pathways by forming a particle-visitation weighted histogram \wK\. Converting the ln(K) dependence of \wK\ into time yields the equivalence of \wK\ and (t), and shows the part of \wK\ that forms the power-law of (t), which is the origin of anomalous transport. We also derive an expression defining the power law exponent in terms of the \wK\ parameters. This equivalence is a remarkable result, particularly given the correlated K-field, the complexity of the flow field and the statistics of the particle transitions.