On Management of Ground Water in Ross Creek Basin, Alberta, Canada
Publication: Journal of Water Resources Planning and Management
Volume 117, Issue 2
Abstract
A basin‐stability‐based hydrological model is formulated for managing the ground water in Ross Creek Basin, Alberta. The model accounts for some deficiencies in the use of the classical aquifer‐hydraulics method of pump testing for evaluating regional ground‐water resources. Although available water resources in the basin exceed the demand for water, the variable nature of the resource requires efficient management of subsurface space in a form precluded by the lack of suitable aquifers. Consequently, analysis of the response of the ground‐water regime to development indicates that only about of ground water can be pumped from the basin on a sustained basis. Simulations indicate that production at this rate does not hinder natural ground‐water discharge from springs at intermediate and higher topographic elevations, but downstream users of the pumping site will be deprived of their water supply. Attempting to pump the ground water to ensure the continued natural discharge of water to downstream users results in a pumping rate near zero. The ground‐water system in Ross Creek Basin should be operated under natural conditions for best results.
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References
1.
Bear, J. (1979). Hydraulics of groundwater. McGraw‐Hill Book Co., New York, N.Y.
2.
Borneuf, D. M. (1976). “Hydrogeology of the foremost area.” Earth Sciences Report 14‐4, Res. Council of Alberta, Edmonton, Alberta.
3.
Davis, L. A., and Neuman, S. P. (1983). Documentation and user's guide: UNSAT2‐Variably saturated flow model. U.S. Nuclear Regulatory Commission, Washington, D.C.
4.
Freeze, R. A. (1968). “Quantitative interpretation of regional groundwater flow patterns as an aid to water balance studies.” Publication No. 77 Int. Association of Scientific Hydr., General Assembly of Berne, Germany, 154–173.
5.
Freeze, R. A., and Cherry, J. A. (1979). Groundwater. Prentice‐Hall, Inc., Englewood Cliffs, N.J.
6.
Freeze, R. A., and Witherspoon, P. A. (1968). “Theoretical analysis of regional groundwater flow, 3. Quantitative interpretations.” Water Resour. Res., 4(3), 581–590.
7.
Frind, E. O. (1982). “Simulation of long‐term transient density‐dependent transport in groundwater.” Advances in Water Resour., 5, 73–88.
8.
Frind, E. O., and Matanga, G. B. (1985). “The dual formulation of flow for contaminant transport modeling, 1: Review of theory and accuracy aspects.” Water Resour. Res., 21(2), 159–169.
9.
Maclean, A. H. (1974). “Soil genesis in relation to groundwater and soil moisture regimes near Vegreville, Alberta,” thesis presented to the University of Alberta, at Edmonton, Alberta, in partial fulfillment of the requirements for the degree of doctor of philosophy.
10.
Meyboom, P. (1966). “Groundwater studies in the Assiniboine River drainage basin: 1. The evaluation of a flow system in south‐central Saskatchewan.” Geol. Surv. Can. Bull., 139, 65.
11.
Ophori, D. U. (1986). “A numerical simulation analysis of regional groundwater flow for basin management: Plains Regions, Alberta,” thesis presented to the University of Alberta, at Edmonton, Alberta, in partial fulfillment of the requirements for the degree of doctor of philosophy.
12.
Ophori, D. U., and Tóth, J. (1986). “A study of groundwater resources development and management in Ross Creek Basin, Alberta.” Final Report, Alberta Environment, Lethbridge, Alberta, 112.
13.
Ophori, D. U., and Tóth, J. (1990). “Influence of the location of production wells in unconfined groundwater basins: An analysis by numerical simulation.” Can. J. Earth Sci., 27(5), 657–668.
14.
Pinder, G. F., and Frind, E. O. (1972). “Application of the Galerkin's procedure to aquifer analysis.” Water Resour. Res., 8(1), 108–120.
15.
Richards, L. A. (1931). “Capillary conduction of liquids through porous mediums.” Physics, 1, 318–333.
16.
Sophocleous, M. A. (1978). “Analysis of heat and water transport in unsaturated‐saturated porous media,” thesis presented to the University of Alberta, at Edmonton, Alberta, in partial fulfillment of the requirements for the degree of doctor of philosophy.
17.
Tóth, J. (1966a). “Groundwater geology, movement, chemistry and resources near Olds, Alberta.” Bulletin 17, Res. Council of Alberta, 126.
18.
Tóth, J. (1966b). “Mapping and interpretation of field phenomena for groundwater reconnaissance in a prairie environment.” Alberta, Canada. Bull. Int. Association Sci. Hydro., 9, 20–68.
19.
Tóth, J. (1970). “A conceptual model of the groundwater regime and the hydrologic environment.” J. Hydrology, 10(2), 164–176.
20.
Tóth, J. (1982). “First approximation of groundwater basin‐parameters and resources from rudimentary water‐level observations in a prairie environment.” Proc. 2nd Nat. Hydrogeological Conf., Int. Association of Hydrogeologists, Winnipeg, Manitoba, 28–34.
21.
Westgate, J. A. (1968). “Surficial geology of the Foremost‐Cypress Hills area.” Bulletin 22, Alberta Research Council of Alberta.
Information & Authors
Information
Published In
Journal of Water Resources Planning and Management
Volume 117 • Issue 2 • March 1991
Pages: 195 - 216
Copyright
Copyright © 1991 ASCE.
History
Published online: Mar 1, 1991
Published in print: Mar 1991
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