A stochastic model for solute transport in porous media: mathematical basis and computational solution
Authors
Date
1999-08
Type
Report
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Fields of Research
Abstract
In this paper, we develop a computational model of solute dispersion in saturated porous media by considering fluid velocity as a fundamental stochastic quantity. The velocity can be considered as having a random part correlated in space and o-correlated in time superimposed on the Darcian velocity. The spatial correlation depends on the geometric and other properties of porous media. The stochastic partial differential equation that describes the mass conservation of a solute in an infinitesimal volume is derived by assuming the variables are irregular, continuous random variables which require higher order terms in the Taylor series to model the spatial variation. This partial differential equation can be written in the form of a stochastic differential equation v.rith a drift term and a diffusion term. The diffusion term can be expressed in terms of a Hibeli space valued Wiener process which is a function of the spatial correlation of the random part of velocity. This spatial correlation is modelled in terms of a covariance function with an exponential kernel
having a fixed correlation length, and Karhunnen-Loeve expansion based on the orthonormal basis functions for the exponential kernel is used in the solution. A numerical scheme was developed to solve the model based on the definition of Ito integral.