Source:Journal of Environmental Radioactivity, Volumes 178–179
Author(s): J.I. McIntyre, C.E. Aalseth, T.R. Alexander, H.O. Back, B.J. Bellgraph, T.W. Bowyer, V. Chipman, M.W. Cooper, A.R. Day, S. Drellack, M.P. Foxe, B.G. Fritz, J.C. Hayes, P. Humble, M.E. Keillor, R.R. Kirkham, E.J. Krogstad, J.D. Lowrey, E.K. Mace, M.F. Mayer, B.D. Milbrath, A. Misner, S.M. Morley, M.E. Panisko, K.B. Olsen, M.D. Ripplinger, A. Seifert, R. Suarez
Pacific Northwest National Laboratory reports on the detection of 39Ar at the location of an underground nuclear explosion on the Nevada Nuclear Security Site. The presence of 39Ar was not anticipated at the outset of the experimental campaign but results from this work demonstrated that it is present, along with 37Ar and 85Kr in the subsurface at the site of an underground nuclear explosion. Our analysis showed that by using state-of-the-art technology optimized for radioargon measurements, it was difficult to distinguish 39Ar from the fission product 85Kr. Proportional counters are currently used for high-sensitivity measurement of 37Ar and 39Ar. Physical and chemical separation processes are used to separate argon from air or soil gas, yielding pure argon with contaminant gases reduced to the parts-per-million level or below. However, even with purification at these levels, the beta decay signature of 85Kr can be mistaken for that of 39Ar, and the presence of either isotope increases the measurement background level for the measurement of 37Ar. Measured values for the 39Ar measured at the site ranged from 36,000 milli- Becquerel/standard-cubic-meter-of-air (mBq/SCM) for shallow bore holes to 997,000 mBq/SCM from the rubble chimney from the underground nuclear explosion.
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