Abstract
A reliability approach is used to develop a probabilistic model of two-dimensional non-reactive and reactive contaminant transport in porous media. The reliability approach provides two important quantitative results: an estimate of the probability that contaminant concentration is exceeded at some location and time, and measures of the sensitivity of the probabilistic outcome to likely changes in the uncertain variables. The method requires that each uncertain variable be assigned at least a mean and variance; in this work we also incorporate and investigate the influence of marginal probability distributions. Uncertain variables includex andy components of average groundwater flow velocity,x andy components of dispersivity, diffusion coefficient, distribution coefficient, porosity and bulk density. The objective is to examine the relative importance of each uncertain variable, the marginal distribution assigned to each variable, and possible correlation between the variables. Results utilizing a two-dimensional analytical solution indicate that the probabilistic outcome is generally very sensitive to likely changes in the uncertain flow velocity. Uncertainty associated with dispersivity and diffusion coefficient is often not a significant issue with respect to the probabilistic analysis; therefore, dispersivity and diffusion coefficient can often be treated for practical analysis as deterministic constants. The probabilistic outcome is sensitive to the uncertainty of the reaction terms for early times in the flow event. At later times, when source contaminants are released at constant rate throughout the study period, the probabilistic outcome may not be sensitive to changes in the reaction terms. These results, although limited at present by assumptions and conceptual restrictions inherent to the closed-form analytical solution, provide insight into the critical issues to consider in a probabilistic analysis of contaminant transport. Such information concerning the most important uncertain parameters can be used to guide field and laboratory investigations.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Cameron, D.R.; Klute, A. 1977: Convective-dispersive solute transport with a combined equilibrium and kinetic adsorption models. Water Resources Research 13 (1), 183–188
Cawlfield, J.D.; Sitar, N. 1988: Stochastic finite element analysis of groundwater flow using the first-order reliability method. In: Peck et al. (eds.) Consequences of spatial variability in aquifer properties and data limitations for groundwater modeling practice. IAHS Pub. No. 175
Cawlfield, J.D.; Wu, M.-C. 1991: Probabilistic analysis of one-dimensional non-reactive and reactive transport in porous media: An examination of the influence of marginal distribution type, correlation and magnitude of uncertainty. Submitted to Water Resources Research (in review)
Chrysikopoulos, C.V.; Kitanidis, P.K.; Roberts, P.V. 1990: Analysis of one-dimensional solute transport through porous media with spatially variable retardation factor. Water Resources Research 26 (3), 437–446
Clifton, P.M.; Neuman, S.P. 1982: Effects of Kriging and inverse modeling on conditional simulation of the avra valley aquifer in southern Arizona. Water Resources Research 18 (4), 1215–1234
Cleary, R.W.; Ungs, M.J. 1978: Analytical models for groundwater pollution and hydrology. Princeton University, Water Resources Program Report No. 78-WR-15, 184 pp.
Dagan, G. 1982: Stochastic modeling of groundwater flow by unconditional and conditional probabilities, 2, The solute transport. Water Resources Research 18 (4), 835–848
Dagan, G. 1986: Statistical theory of groundwater flow and transport: Pore to laboratory, laboratory to formation, and formation to regional scale. Water Resources Research 22 (9), 120S-134S
Der Kiureghian, A.; Lin, H.-L.; Hwang, S.-J. 1987: Second-order reliability approximations. ASCE, J. Engineering Mechanics 113 (8), 1208–1225
Der Kiureghian, A.; Liu, P.-L. 1985: Structural reliability under incomplete probability information. Rep. UCB/SESM-85/01, Dept. of Civil Eng., Univ. of Cal., Berkeley
Der Kiureghian, A.; Liu, P.-L. 1986: Structural reliability under incomplete probability information. ASCE, J. Engineering Mechanics 112 (1), 85–104
Freeze, R.A. 1975: A stochastic-conceptual analysis of one-dimensional groundwater flow in non-uniform homogeneous media. Water Resources Research 11 (5), 725–741
Freeze, R.A.; Massmann, J.; Smith, L.; Sperling, T.; James, B. 1990: Hydrogeological decision analysis. 1. A framework. Groundwater 28, 738–766
Gelhar, L.W. 1984: Stochastic analysis of flow in heterogeneous porous media. In: Bear, J; Corapciolglu, M. (eds.) Fundamentals of transport phenomena in porous media, pp. 673–720. Martinus Nijhoff Publishers, Dordrecht
Gelhar, L.W. 1986: Stochastic subsurface hydrology from theory to applications. Water Resources Research 22 (13), 135S-145S
Gelhar, L.W.; Axness, C.L. 1984: Three-dimensional stochastic analysis of macrodispersion in aquifers. Water Resources Research 19 (1), 161–180
Hasofer, A.M.; Lind, N.C. 1974: Exact and invariant second-moment code format. ASCE, Journal of the Engineering Mechancis Div. 100 (EM1), 111–121
Javandel, I.; Doughty, C.; Tsang, C.F. 1984: Ground water transport: Handbook of mathematical models. American Geophysical Union, Water Resources Monograph Series No. 10, 228 pp.
Jones, L. 1989: Some results comparing Monte Carlo simulation and first order Taylor series approximation for steady groundwater flow. Stochastic Hydrol. and Hydraulics 3 (3), 179–190
Liu, P.-L.; Der Kiureghian, A. 1988: Optimization algorithms for structural reliability. ASME, Computational Probabilistic Mechanics ADM-93, 185–196
Madsen, H.O.; Krenk, S.; Lind, N.C. 1986: Methods of structural safety. Prentice-Hall Inc., Englewood Cliffs, N.J.
Massmann, J.; Freeze, R.A.; Smith, L.; Sperling, T.; James, B. 1991: Hydrogeological decision analysis. 2. Applications to groundwater contamination. Groundwater (in press)
Perkins, T.K.; Johnston, O.C. 1963: A review of diffusion and dispersion in porous media. Society of Petroleum Engineering, Journal 3, 70–84
Rackwitz, R.; Fiessler, B. 1978: Structural reliability under combined load sequences. Computers and Structures 9, 489–494
Sitar, N.; Cawlfield, J.D.; Der Kiureghian, A. 1987: First-order reliability approach to stochastic analysis of subsurface flow and contaminant transport. Water Resources Research 23 (5), 794–804
Smith, L.; Freeze, R.A. 1979: Stochastic analysis of steady state groundwater flow in a bounded domain, 2, Two-dimensional simulation. Water Resources Research 15 (6), 1543–1559
Smith, L.; Schwartz, F.W. 1980: Mass transport, 1, Stochastic analysis of macrodispersion. Water Resources Research 16 (2), 303–313
Tang, D.H.; Pinder, G.F. 1977: Simulation of groundwater flow and mass transport. Advan. Water Resources 1 (1), 25–30
Travis, C.C. 1978: Mathematical description of adsorption and transport of reactive solutes in soil: A review of selected literatures. ORNL-5403, 65 pp.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Wu, M.C., Cawlfield, J.D. Probabilistic sensitivity and modeling of two-dimensional transport in porous media. Stochastic Hydrol Hydraul 6, 103–121 (1992). https://doi.org/10.1007/BF01591333
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01591333