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Transport of 14C and Uranium in the Carrizo Aquifer of South Texas, a Natural Analog of Radionuclide Migration

Published online by Cambridge University Press:  25 February 2011

Robert W. Andrews  and
F. J. Pearson Jr.
Robert W. Andrews
Affiliation:
INTERA Environmental Consultants, Inc.,11999 Katy Freeway,Suite 610,Houston,Texas 77079
F. J. Pearson Jr.
Affiliation:
INTERA Environmental Consultants, Inc.,11999 Katy Freeway,Suite 610,Houston,Texas 77079
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Abstract

Ground-water flow and transport were modeled along a one-dimensional, vertical cross-section of the Carrizo aquifer from its outcrop down gradient for 100 km. Using a constant flux of 14C at the recharge boundary, the 14C mass fraction distribution downgradient was simulated until steady-state was attained. The match between the observed data and simulated results is excellent for a porosity of 35% and a KD of zero. The transport of both 234U and 238U was simulated with varying retardation coefficients. The best fit occurred with a RD of about 30, which corresponds to a KD of 6. The results indicate that modeling may be reliably conducted over time periods and distances of interest in radionuclide transport performance assessments and that regionally averaged hydrologic properties can provide appropriate values for predicting ground-water flow and nuclide transport.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 26: Symposium D – Scientific Basis for Nuclear Waste Management VII , 1983 , 1085
Copyright
Copyright © Materials Research Society 1984

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References

REFERENCES

1. Klempt, W.B., Duffin, G.L., and Elder, G.F., Ground-water Resources of the Carrizo Aquifer in the Winter Garden Area of Texas: Texas Water Development Board Report 210, v. 1 (1976)Google Scholar
2. Galloway, W.E., Finley, R.J., and Henry, C.D., South Texas Uranium Province-Geologic Perspective, Guidebook 18, Texas Bureau of Economic Geology, Austin, TX (1979)Google Scholar
3. Cowart, J.B. and Osmond, J.K., Uranium Isotopes in Ground Water as a Prospecting Technique, prepared for U.S. Department of Enerqv, Grand Junction, Co, GJBX-119(80) (1980)Google Scholar
4. Alexander, W.J. and White, D.E., Ground-Water Resources of Atascosa and Frio Counties, Texas, Report 32, Texas Water Development Board, Austin, TX (1966)Google Scholar
5. Payne, J.N., Geohydrologic Significance of Lithofacies of the Carrizo Sand of Arkansas, Louisiana and Texas and the Meridian Sand of Mississippi, U.S. Geological Survey Professional Paper 569-D (1975)Google Scholar
6. Pearson, F.J. Jr., and White, D.E., Carbon-14 ages and flow rates of water in Carrizo sand, Atascosa County Texas, Water Resources Research, v. 3, p. 251261 (1967)Google Scholar
7. Cowart, J.B. and Osmond, J.K., 234U and 238U in the Carrizo Sandstone aquifer of south Texas: in Isotope Techniques in Groundwater Hydrology 1974: Internat. Atomic Energy Agency, Vienna, v. II, P. 131149 (1974)Google Scholar
8. INTERA Environmental Consultants, SWENT, A Three-Dimensional Finite Difference Code for the Simulation of Fluid, Energy, and Solute Radionuclide Transport, ONWI-457, prepared for Office of Nuclear Waste Isolation, Battelle Memoria Institute, Columbus, OH. (1983)Google Scholar
9. Allard, B., Torstenfelt, B., and Andersson, K., Sorption Studies of H14CO3 -on some Geoloqic Media and Concrete, in Proceedings of the Third International Symposium on the Scientific Basis for Nuclear Waste Management, p. 465472 (1981)Google Scholar
10. Valocchi, A.J., Street, R.L., and Roberts, P.V., Transnort of Ion Exchanging Solutes in Groundwater: Chromatographic Theory and Field Simulation, Water Resources Research, v. 17, p. 1517–1527 (1981)Google Scholar
11. Pearson, F.J. Jr., Noronha, C.J., and Andrews, R.W., Mathematical Modeling of the Distribution of Natural 14C, 234U, and 238U in a Regional Ground-Water System, Radiocarbon, v. 25, p. 291300 (1983)Google Scholar