@article{oai:kanazawa-u.repo.nii.ac.jp:00029423,
 author = {小村, 和久 and Greenfield, Mark B. and Ito, N. and Iwata, A. and Kubo, K. and Ishigaki, M. and Komura, Kazuhisa},
 issue = {7},
 journal = {Journal of Applied Physics},
 month = {Jan},
 note = {The relative γ ray activities from P 214 b and B 214 i condensed from precipitation are used to determine its "age," the average time the accreted activity has been removed from secular equilibrium. A verifiable assumption that radon progeny on/in the surface/volume of droplets mostly remains in secular equilibrium until they begin their descent, enables estimates of their transit times to ground of typically a few tens of minutes. This agrees well with the time expected for the activity on the surface of droplets to reach the ground from heights of a few kilometers. The half lives of γ activities from B 214 i and P 214 b, 19.7 and 26.9 min, respectively, are on the same scale as transit time to ground and close enough to each other to measure ratios of activities from secular equilibrium (1.00) to transient equilibrium (3.88) within a few hundreds of minutes. The ratio of γ count rates is independent of knowledge of either initial activity or any systematic errors and thus limited only by the uncertainty from counting statistics, which from condensates of 5-30 l of rain viewed with 2π solid angle by a 50% efficient, high-resolution Ge detector is only a few percent. These ratios fit extremely well to known theoretical curves, which cannot only be used to date rain but can also be extrapolated backward to determine radon progeny activities in rain prior to its descent, knowledge of which may facilitate further studies using radon progeny as tracers. © 2008 American Institute of Physics., 金沢大学自然計測応用研究センター自然計測研究部門},
 title = {Determination of rain age via γ rays from accreted radon progeny},
 volume = {104},
 year = {2008}
}