Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-25T17:51:39.507Z Has data issue: false hasContentIssue false

Uranium-Lead Radiometric Age Determinations of Naturally Occurring U(VI) Minerals: Application to Radwaste Storage

Published online by Cambridge University Press:  15 February 2011

Douglas G. Brookins*
Affiliation:
Department of Geology, University of New Mexico, Albuquerque, NM 87131
Get access

Abstract

U(VI) bearing species are commonly formed under oxidizing laboratory rock-water-HLW experimental conditions. The experimental stability of artificially produced Na-Cs-Rb weeksite (alkali uranyl hydrosilicate), and other U(VI) species, is uncertain. Naturally occurring U(VI) bearing minerals (uranophane and tyuyamutrite) from the Grants mineral belt, New Mexico, have been studied for their U-Pb systematics as natural analogs to these experimentally produced phases. Samples from highly oxidized rocks and from chemically reducing environments have been studied. The samples from oxidized rocks are mixed with hematite-barite-gypsum-calcite gangue and are close to, but not in contact with, pyritiferous-organic carbon-uraniferous (U(NIV))-chloritic are. The reduced rock uranophane yields nearly concordant238U - 206Pb and 235U - 207Pb ages of 8.32 and 8.33 MYBP (millions of years before the present); the oxidized rock uranophane and tyuyam .nite yield more discordant ages (n=8) between 7.4 and 2.7 MYBP. These data argue for long range stability of U(VI)-rich phases in the geologic environment.

Type
Research Article
Copyright
Copyright © Materials Research Society 1982

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1. McCarthy, G. J. et al. , Simulated high-level waste-basalt interaction experiments: first interim progress report: U. S. D. O. E. EY–77–C–06–1030 (SA–904), 66 pp. (1978).Google Scholar
2. McCarthy, G. J. et al. , Reaction of water with a simulated high-level nuclear waste glass at 300°C, 300 bars: U. S. D. O. E. EY–77–C–06–1030 (SA–904), 65 pp. (1978).Google Scholar
3. McCarthy, G. J. et al. , Nature 273, 217 (1978).Google Scholar
4. McCarthy, G. J. et al. , in Sci. Basis for Nuc. Waste Mngt. I, McCarthy, G. J., Ed. (Plenum Press, NY) pp. 329350 (1979).Google Scholar
5. Brookins, D. G., Mineralium Deposita 16, 3 (1981).Google Scholar
6. Brookins, D. G., Isochron/West (in press).Google Scholar
7. Brookins, D. G., Uranium deposits of the Grants, New Mexico mineral Belt II: U. S. D. O. E./B. F. E. C. 76–029E, 411 pp. (1979).Google Scholar
8. Garrels, R. M. and Christ, C. L., Solutions, minerals and equilibria: (Harper and Ros, New York) 450 pp. (1965).Google Scholar
9. Finch, W. I., U. S. G. S. Prof. Ppr. 538, 121 pp. (1967).Google Scholar
10. Stern, T. W. and Stieff, L. R., in U. S. G. S. Prof. Ppr. 320, R. M. Garrels and E. S. Larsen, Eds., pp. 151–156 (1959).Google Scholar
11. Brookins, D. G., unpub. rpt. to Los Alamos Ntl. Laboratory, 151 pp. (1981).Google Scholar
12. Scheetz, B. et al. , in Sci. Basis for Nac. Waste Mngt., II, Northrop, C.N., Ed. (Plenum Press, N.Y.) pp. 207214.Google Scholar