Over the past two decades percolation theory has been used to explain and model a wide
variety of phenomena that are of industrial and scientific importance. Examples include …

Simulations of the random barrier model show that ac currents at extreme disorder are
carried almost entirely by the percolating cluster slightly above threshold; thus contributions …

We describe a new approach for simulation of multiphase flows through heterogeneous
porous media, such as oil reservoirs. The method, which is based on the wavelet …

Modeling flow and solute transport in large-scale (eg) on the order of 10 3 m heterogeneous
porous media involves substantial computational burden. A common approach to alleviate …

Wavelet transforms (WTs) constitute a class of powerful tools for spectral and local analysis
of data, such as time series, geophysical data, and well logs, as well as modeling of various …

We have developed an accurate and highly efficient method for upscaling and simulation of
immiscible displacements in three-dimensional (3D) heterogeneous reservoirs, which is an …

Performing statistical evaluations, coupling Schrödinger's equation and Poisson's equation
self-consistently, and employing an iterative fitting process, we have obtained a simple …

Discrete fracture modeling (DFM) is currently the most promising approach for modeling of
naturally fractured reservoirs and simulation of multiphase fluid flow therein. In contrast with …

We have developed a multiscale self-consistent method to study the charge conductivity of a
porous system or a metallic matrix alloyed by randomly distributed nonmetallic grains and …

Using extensive Monte Carlo simulations, we study the growth of films by ballistic deposition
of rodlike particles with various sizes on a one-dimensional substrate. Particles are …