This paper discusses the results of numerical analysis of dispersion of passive solutes in twodimensional heterogeneous porous formations. Statistics of flow and transport variables, the accuracy and the role of approximations implicit in existing first-order theories, and the convergence of computational results are investigated. The results suggest that quite different rates of convergence with Monte Carlo runs hold for different spatial moments and that over 1000 realizations are required to stabilize second moments even for relatively mild heterogeneity (rr• < 1.6). This has implications for the extent of the spatial domain for single-realization numerical studies of the same type. A comparison of the variance of plumes with the results of linear theories (0.05 < rr•, < 1.6) shows an unexpectedly broad validity field for the theoretical solution obtained from a suitable linearization of flow and transport. Reformulation of the same problem linearizing in turn the flow or the transport Recent experimental evidence and theoretical results suggest that the transport of passive solutes in natural porous formations is dominated by the spatial variations in hydrau-!ic conductivity resulting in heterogeneous convection fields (see, for an exhaustive review, Dagan [1989]). A theory of flow and transport has been developing in recent years , 1990] which links the kinematics of the dispersion process to field measurable quantities, i.e., the spatial correlation structure and the variability of the log conductivity field Y(x) of porous formations viewed as a random space function. Fundamental experimental validations from accurate field analyses and critical elaborations of the data support the validity of linear theories at least for mildly heterogeneous aquifers [e.g.McLaughlin, 1991; Le Blanc et al., 1991, Garabedian et al., 1991; Rajaram and Gelhar, 1991]. Limits and validity of the theory of flow and transport in heterogeneous porous formations have recently been discussed IDagan, 1989]. It is accepted that the linear (denoted here as Dagan's) theory subsumes a number of previous results [Matheron and de Marsily, 1980; Dagan, 1984; Gelhar and Axness, 1983; Dagan, 1987] and captures the foremost features of the processes whenever the variance of log conductivity •r2r, a significant measure of heterogeneity, is small (cr• < 1) because a first-order perturbation is used as a consistent approximation involving such a parameter. Zhang, Y. K., and S. P. Neuman, A quasi-linear theory of non-Fickian and Fickian subsurface dispersion, 2, Application to anisotropic media and the Borden site, Water Resour. Res., 26(5), 903-913, 1990.
