Mathematical Modeling of the Distribution of Natural 14C, 234U, and 238U in a Regional Ground-Water System

F J Pearson; C J Noronha; R W Andrews

doi:10.1017/S0033822200005609

Extract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Increasing concern with nuclear waste isolation technology is leading to additional studies of naturally occurring isotopes in ground water. Such studies provide information on 1) the use of radionuclides to estimate ground-water travel times and/or residence times. This information can he an extremely useful adjunct to conventional hydrologic data in developing the understanding of regional hydrology needed in the site selection process, and 2) the use of natural radionuclides as analogues to the behavior of radionuclides of concern in nuclear waste.

References

Anderson, M P, 1979, Using models to simulate the movement of contaminants through groundwater flow systems: CRC Critical Rev Environmental Control, v 9, p 97–156.Google Scholar

Cowart, J B and Osmond, J K, 1974, ²³⁴U and ²³⁸U in the Carrizo Sandstone aquifer of south Texas, in Isotope Techniques in Groundwater Hydrology 1974: IAEA, Vienna, v 2, p 131–149.Google Scholar

Klempt, W B, Duffin, G L, and Elder, G R, 1976, Ground-water resources of the Carrizo Aquifer in the Winter Garden area of Texas: Texas Water Development Bd Rept 210, v 1, 73 P.Google Scholar

Oeschger, Hans, 1974, Discussion in Isotope Techniques in Groundwater Hydrology 1974: IAEA, Vienna, v 2, p 91.Google Scholar

Pearson, F J Jr, and White, D E, 1967, Carbon-14 ages and flow rates of water in Carrizo sand, Atascosa County, Texas: Water Resources Research, v 3, p 151–161.CrossRef Google Scholar

Pickens, J F and Grisak, F E, 1981, Modeling of scale dependent dispersion in hydrogeologic systems: Water Resources Research, v 17, p 1701–1711.CrossRef Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Andrews, Robert W. and Pearson, F. J. 1983. Transport of 14C and Uranium in the Carrizo Aquifer of South Texas, a Natural Analog of Radionuclide Migration. MRS Proceedings, Vol. 26, Issue. ,

Brandstetter, Albin Kroitoru, Levy Andrews, Robert W. and Thackston, John W. 1983. Geohydrology Surrounding a Potential High-Level Nuclear Waste Repository in the Paradox Basin, Utah. MRS Proceedings, Vol. 26, Issue. ,

Dickson, B.L. and Davidson, M.R. 1985. Interpretation of activity ratios in groundwaters. Chemical Geology: Isotope Geoscience section, Vol. 58, Issue. 1-2, p. 83.

Phillips, Fred M. Tansey, Michael K. Peeters, Leslie A. Cheng, Songlin and Long, Austin 1989. An isotopic investigation of groundwater in the Central San Juan Basin, New Mexico: Carbon 14 dating as a basis for numerical flow modeling. Water Resources Research, Vol. 25, Issue. 10, p. 2259.

Geyh, Mebus A. and Schleicher, Helmut 1990. Absolute Age Determination. p. 381.

Ivanovich, M. Fröhlich, K. and Hendry, M.J. 1991. Uranium-series radionuclides in fluids and solids, Milk River aquifer, Alberta, Canada. Applied Geochemistry, Vol. 6, Issue. 4, p. 405.

1991. Technical Report 88-01. Vol. 43, Issue. , p. 421.

Alexander, W.R. and McKinley, I.G. 1992. A review of the application of natural analogues in performance assessment: improving models of radionuclide transport in groundwaters. Journal of Geochemical Exploration, Vol. 46, Issue. 1, p. 83.

Lehmann, Bernhard E. Davis, Stanley N. and Fabryka‐Martin, June T. 1993. Atmospheric and subsurface sources of stable and radioactive nuclides used for groundwater dating. Water Resources Research, Vol. 29, Issue. 7, p. 2027.

Bonotto, D.M. and Andrews, J.N. 1993. The mechanism of 234U238U activity ratio enhancement in karstic limestone groundwater. Chemical Geology, Vol. 103, Issue. 1-4, p. 193.

Griffault, Lise Y. Gascoyne, Mel Kamineni, Choudari Kerrich, Robert and Vandergraaf, Tjalle T. 1993. Actinide and rare earth element characteristics of deep fracture zones in the Lac du Bonnet granitic batholith, Manitoba, Canada. Geochimica et Cosmochimica Acta, Vol. 57, Issue. 6, p. 1181.

1994. Natural Analogue Studies in the Geological Disposal of Radioactive Wastes. Vol. 57, Issue. , p. 337.

Osmond, J. Kenneth and Cowart, James B. 2000. Environmental Tracers in Subsurface Hydrology. p. 145.

Geyh, Mebus A 2000. An Overview of 14C Analysis in the Study of Groundwater. Radiocarbon, Vol. 42, Issue. 1, p. 99.

Phillips, F.M. and Castro, M.C. 2003. Treatise on Geochemistry. p. 451.

Glynn, Pierre D. and Plummer, L. Niel 2005. Geochemistry and the understanding of ground-water systems. Hydrogeology Journal, Vol. 13, Issue. 1, p. 263.

Geyh, M.A. 2005. Isotopes in the Water Cycle. p. 221.

Sahl, Jason W. Schmidt, Raleigh Swanner, Elizabeth D. Mandernack, Kevin W. Templeton, Alexis S. Kieft, Thomas L. Smith, Richard L. Sanford, William E. Callaghan, Robert L. Mitton, Jeffry B. and Spear, John R. 2008. Subsurface Microbial Diversity in Deep-Granitic-Fracture Water in Colorado. Applied and Environmental Microbiology, Vol. 74, Issue. 1, p. 143.

Phillips, F.M. and Castro, M.C. 2014. Treatise on Geochemistry. p. 361.

Zang, Hongfei Zheng, Xiuqing Qin, Zuodong and Jia, Zhenxing 2015. A study of the characteristics of karst groundwater circulation based on multi-isotope approach in the Liulin spring area, North China. Isotopes in Environmental and Health Studies, Vol. 51, Issue. 2, p. 271.

Download full list

Article contents

Mathematical Modeling of the Distribution of Natural 14C, 234U, and 238U in a Regional Ground-Water System

Extract

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests